diff --git a/Modules/DiffusionImaging/DiffusionCore/IODataStructures/Properties/mitkDiffusionPropertyHelper.cpp b/Modules/DiffusionImaging/DiffusionCore/IODataStructures/Properties/mitkDiffusionPropertyHelper.cpp
index 6421f65a8b..b2e253b1bb 100644
--- a/Modules/DiffusionImaging/DiffusionCore/IODataStructures/Properties/mitkDiffusionPropertyHelper.cpp
+++ b/Modules/DiffusionImaging/DiffusionCore/IODataStructures/Properties/mitkDiffusionPropertyHelper.cpp
@@ -1,418 +1,416 @@
 /*===================================================================
 
 The Medical Imaging Interaction Toolkit (MITK)
 
 Copyright (c) German Cancer Research Center,
 Division of Medical and Biological Informatics.
 All rights reserved.
 
 This software is distributed WITHOUT ANY WARRANTY; without
 even the implied warranty of MERCHANTABILITY or FITNESS FOR
 A PARTICULAR PURPOSE.
 
 See LICENSE.txt or http://www.mitk.org for details.
 
 ===================================================================*/
 
 #include "mitkDiffusionPropertyHelper.h"
 #include <mitkITKImageImport.h>
 #include <mitkImageCast.h>
 #include <itkImageRegionIterator.h>
 #include <mitkProperties.h>
 
 const std::string mitk::DiffusionPropertyHelper::GRADIENTCONTAINERPROPERTYNAME = "meta.GradientDirections";
 const std::string mitk::DiffusionPropertyHelper::ORIGINALGRADIENTCONTAINERPROPERTYNAME = "meta.OriginalGradientDirections";
 const std::string mitk::DiffusionPropertyHelper::MEASUREMENTFRAMEPROPERTYNAME = "meta.MeasurementFrame";
 const std::string mitk::DiffusionPropertyHelper::REFERENCEBVALUEPROPERTYNAME = "meta.ReferenceBValue";
 const std::string mitk::DiffusionPropertyHelper::BVALUEMAPPROPERTYNAME = "BValueMap";
 
 mitk::DiffusionPropertyHelper::DiffusionPropertyHelper()
 {
 }
 
 mitk::DiffusionPropertyHelper::DiffusionPropertyHelper( mitk::Image* inputImage)
   : m_Image( inputImage )
 {
   // Update props
 }
 
 mitk::DiffusionPropertyHelper::~DiffusionPropertyHelper()
 {
 }
 
 
 mitk::DiffusionPropertyHelper::ImageType::Pointer mitk::DiffusionPropertyHelper::GetItkVectorImage(mitk::Image* image)
 {
     ImageType::Pointer vectorImage = ImageType::New();
     mitk::CastToItkImage(image, vectorImage);
     return vectorImage;
 }
 
 mitk::DiffusionPropertyHelper::GradientDirectionsContainerType::Pointer
   mitk::DiffusionPropertyHelper::CalcAveragedDirectionSet(double precision, GradientDirectionsContainerType::Pointer directions)
 {
   // save old and construct new direction container
   GradientDirectionsContainerType::Pointer newDirections = GradientDirectionsContainerType::New();
 
   // fill new direction container
   for(GradientDirectionsContainerType::ConstIterator gdcitOld = directions->Begin();
     gdcitOld != directions->End(); ++gdcitOld)
   {
     // already exists?
     bool found = false;
     for(GradientDirectionsContainerType::ConstIterator gdcitNew = newDirections->Begin();
       gdcitNew != newDirections->End(); ++gdcitNew)
     {
       if(AreAlike(gdcitNew.Value(), gdcitOld.Value(), precision))
       {
         found = true;
         break;
       }
     }
 
     // if not found, add it to new container
     if(!found)
     {
       newDirections->push_back(gdcitOld.Value());
     }
   }
 
   return newDirections;
 }
 
 void mitk::DiffusionPropertyHelper::AverageRedundantGradients(double precision)
 {
 
   mitk::GradientDirectionsProperty* DirectionsProperty = static_cast<mitk::GradientDirectionsProperty*>( m_Image->GetProperty(mitk::DiffusionPropertyHelper::GRADIENTCONTAINERPROPERTYNAME.c_str()).GetPointer() );
   GradientDirectionsContainerType::Pointer oldDirs = DirectionsProperty->GetGradientDirectionsContainer();
 
   GradientDirectionsContainerType::Pointer newDirs =
     CalcAveragedDirectionSet(precision, oldDirs);
 
   // if sizes equal, we do not need to do anything in this function
   if(oldDirs->size() == newDirs->size())
     return;
 
   // new image
   ImageType::Pointer oldImage = ImageType::New();
   mitk::CastToItkImage( m_Image, oldImage);
   ImageType::Pointer newITKImage = ImageType::New();
   newITKImage->SetSpacing( oldImage->GetSpacing() );   // Set the image spacing
   newITKImage->SetOrigin( oldImage->GetOrigin() );     // Set the image origin
   newITKImage->SetDirection( oldImage->GetDirection() );  // Set the image direction
   newITKImage->SetLargestPossibleRegion( oldImage->GetLargestPossibleRegion() );
   newITKImage->SetVectorLength( newDirs->size() );
   newITKImage->SetBufferedRegion( oldImage->GetLargestPossibleRegion() );
   newITKImage->Allocate();
 
   // average image data that corresponds to identical directions
   itk::ImageRegionIterator< ImageType > newIt(newITKImage, newITKImage->GetLargestPossibleRegion());
   newIt.GoToBegin();
   itk::ImageRegionIterator< ImageType > oldIt(oldImage, oldImage->GetLargestPossibleRegion());
   oldIt.GoToBegin();
 
   // initial new value of voxel
   ImageType::PixelType newVec;
   newVec.SetSize(newDirs->size());
   newVec.AllocateElements(newDirs->size());
 
   // find which gradients should be averaged
   GradientDirectionsContainerType::Pointer oldDirections = oldDirs;
   std::vector<std::vector<int> > dirIndices;
   for(GradientDirectionsContainerType::ConstIterator gdcitNew = newDirs->Begin();
     gdcitNew != newDirs->End(); ++gdcitNew)
   {
     dirIndices.push_back(std::vector<int>(0));
     for(GradientDirectionsContainerType::ConstIterator gdcitOld = oldDirs->Begin();
       gdcitOld != oldDirections->End(); ++gdcitOld)
     {
       if(AreAlike(gdcitNew.Value(), gdcitOld.Value(), precision))
       {
         //MITK_INFO << gdcitNew.Value() << "  " << gdcitOld.Value();
         dirIndices[gdcitNew.Index()].push_back(gdcitOld.Index());
       }
     }
   }
 
   //int ind1 = -1;
   while(!newIt.IsAtEnd())
   {
 
     // progress
     //typename ImageType::IndexType ind = newIt.GetIndex();
     //ind1 = ind.m_Index[2];
 
     // init new vector with zeros
     newVec.Fill(0.0);
 
     // the old voxel value with duplicates
     ImageType::PixelType oldVec = oldIt.Get();
 
     for(unsigned int i=0; i<dirIndices.size(); i++)
     {
       // do the averaging
       const unsigned int numavg = dirIndices[i].size();
       unsigned int sum = 0;
       for(unsigned int j=0; j<numavg; j++)
       {
         //MITK_INFO << newVec[i] << " << " << oldVec[dirIndices[i].at(j)];
         sum += oldVec[dirIndices[i].at(j)];
       }
       if(numavg == 0)
       {
         MITK_ERROR << "VectorImage: Error on averaging. Possibly due to corrupted data";
         return;
       }
       newVec[i] = sum / numavg;
     }
 
     newIt.Set(newVec);
 
     ++newIt;
     ++oldIt;
   }
 
   mitk::GrabItkImageMemory( newITKImage, m_Image );
 
   m_Image->SetProperty( mitk::DiffusionPropertyHelper::GRADIENTCONTAINERPROPERTYNAME.c_str(), mitk::GradientDirectionsProperty::New( newDirs ) );
   m_Image->SetProperty( mitk::DiffusionPropertyHelper::ORIGINALGRADIENTCONTAINERPROPERTYNAME.c_str(), mitk::GradientDirectionsProperty::New( newDirs ) );
   ApplyMeasurementFrame();
   UpdateBValueMap();
   std::cout << std::endl;
 }
 
 void mitk::DiffusionPropertyHelper::ApplyMeasurementFrame()
 {
 
   if(  m_Image->GetProperty(mitk::DiffusionPropertyHelper::ORIGINALGRADIENTCONTAINERPROPERTYNAME.c_str()).IsNull() )
   {
     return;
   }
 
   GradientDirectionsContainerType::Pointer  originalDirections = static_cast<mitk::GradientDirectionsProperty*>( m_Image->GetProperty(mitk::DiffusionPropertyHelper::ORIGINALGRADIENTCONTAINERPROPERTYNAME.c_str()).GetPointer())->GetGradientDirectionsContainer();
 
   MeasurementFrameType  measurementFrame = GetMeasurementFrame(m_Image);
 
   GradientDirectionsContainerType::Pointer directions = GradientDirectionsContainerType::New();
 
   if( originalDirections.IsNull() || ( originalDirections->size() == 0 ) )
   {
     // original direction container was not set
     return;
   }
 
   int c = 0;
   for(GradientDirectionsContainerType::ConstIterator gdcit = originalDirections->Begin();
       gdcit != originalDirections->End(); ++gdcit)
   {
     vnl_vector<double> vec = gdcit.Value();
     vec = vec.pre_multiply(measurementFrame);
-    MITK_INFO << gdcit.Value();
     directions->InsertElement(c, vec);
     c++;
   }
 
   m_Image->SetProperty( mitk::DiffusionPropertyHelper::GRADIENTCONTAINERPROPERTYNAME.c_str(), mitk::GradientDirectionsProperty::New( directions ) );
 }
 
 void mitk::DiffusionPropertyHelper::UpdateBValueMap()
 {
   BValueMapType b_ValueMap;
 
   if(m_Image->GetProperty(mitk::DiffusionPropertyHelper::BVALUEMAPPROPERTYNAME.c_str()).IsNull())
   {
   }
   else
   {
     b_ValueMap = static_cast<mitk::BValueMapProperty*>(m_Image->GetProperty(mitk::DiffusionPropertyHelper::BVALUEMAPPROPERTYNAME.c_str()).GetPointer() )->GetBValueMap();
   }
 
   if(!b_ValueMap.empty())
   {
     b_ValueMap.clear();
   }
 
   if( m_Image->GetProperty(mitk::DiffusionPropertyHelper::GRADIENTCONTAINERPROPERTYNAME.c_str()).IsNotNull() )
   {
     GradientDirectionsContainerType::Pointer directions = static_cast<mitk::GradientDirectionsProperty*>( m_Image->GetProperty(mitk::DiffusionPropertyHelper::GRADIENTCONTAINERPROPERTYNAME.c_str()).GetPointer() )->GetGradientDirectionsContainer();
 
     GradientDirectionsContainerType::ConstIterator gdcit;
     for( gdcit = directions->Begin(); gdcit != directions->End(); ++gdcit)
     {
-        MITK_INFO << gdcit.Value();
       b_ValueMap[GetB_Value(gdcit.Index())].push_back(gdcit.Index());
     }
   }
 
   m_Image->SetProperty( mitk::DiffusionPropertyHelper::BVALUEMAPPROPERTYNAME.c_str(), mitk::BValueMapProperty::New( b_ValueMap ) );
 }
 
 bool mitk::DiffusionPropertyHelper::AreAlike(GradientDirectionType g1,
                                                 GradientDirectionType g2,
                                                 double precision)
 {
   GradientDirectionType diff = g1 - g2;
   GradientDirectionType diff2 = g1 + g2;
   return diff.two_norm() < precision || diff2.two_norm() < precision;
 }
 
 float mitk::DiffusionPropertyHelper::GetB_Value(unsigned int i)
 {
   GradientDirectionsContainerType::Pointer directions = static_cast<mitk::GradientDirectionsProperty*>( m_Image->GetProperty(mitk::DiffusionPropertyHelper::GRADIENTCONTAINERPROPERTYNAME.c_str()).GetPointer() )->GetGradientDirectionsContainer();
 
   float b_value = static_cast<mitk::FloatProperty*>(m_Image->GetProperty(mitk::DiffusionPropertyHelper::REFERENCEBVALUEPROPERTYNAME.c_str()).GetPointer() )->GetValue();
 
   if(i > directions->Size()-1)
     return -1;
 
   if(directions->ElementAt(i).one_norm() <= 0.0)
   {
     return 0;
   }
   else
   {
     double twonorm = directions->ElementAt(i).two_norm();
     double bval = b_value*twonorm*twonorm;
 
     if (bval<0)
       bval = ceil(bval - 0.5);
     else
       bval = floor(bval + 0.5);
 
     return bval;
   }
 }
 
 void mitk::DiffusionPropertyHelper::InitializeImage()
 {
   this->ApplyMeasurementFrame();
   this->UpdateBValueMap();
 
   // initialize missing properties
   mitk::MeasurementFrameProperty::Pointer mf = dynamic_cast<mitk::MeasurementFrameProperty *>( m_Image->GetProperty(MEASUREMENTFRAMEPROPERTYNAME.c_str()).GetPointer());
   if( mf.IsNull() )
   {
     //no measurement frame present, identity is assumed
     MeasurementFrameType identity;
     identity.set_identity();
     m_Image->SetProperty( mitk::DiffusionPropertyHelper::MEASUREMENTFRAMEPROPERTYNAME.c_str(), mitk::MeasurementFrameProperty::New( identity ));
   }
 }
 
 bool mitk::DiffusionPropertyHelper::IsDiffusionWeightedImage(const mitk::DataNode* node)
 {
     return IsDiffusionWeightedImage(dynamic_cast<mitk::Image *>(node->GetData()));
 }
 
 
 bool mitk::DiffusionPropertyHelper::IsDiffusionWeightedImage(const mitk::Image * image)
 {
   bool isDiffusionWeightedImage( true );
 
   if( image == NULL )
   {
     isDiffusionWeightedImage = false;
   }
 
   if( isDiffusionWeightedImage )
   {
     mitk::FloatProperty::Pointer referenceBValue = dynamic_cast<mitk::FloatProperty *>(image->GetProperty(REFERENCEBVALUEPROPERTYNAME.c_str()).GetPointer());
 
     if( referenceBValue.IsNull() )
     {
       isDiffusionWeightedImage = false;
     }
 
   }
 
   unsigned int gradientDirections( 0 );
   if( isDiffusionWeightedImage )
   {
     mitk::GradientDirectionsProperty::Pointer gradientDirectionsProperty = dynamic_cast<mitk::GradientDirectionsProperty *>(image->GetProperty(GRADIENTCONTAINERPROPERTYNAME.c_str()).GetPointer());
 
     if( gradientDirectionsProperty.IsNull() )
     {
       isDiffusionWeightedImage = false;
     }
     else
     {
       gradientDirections = gradientDirectionsProperty->GetGradientDirectionsContainer()->size();
     }
   }
 
   if( isDiffusionWeightedImage )
   {
     unsigned int components = image->GetPixelType().GetNumberOfComponents();
 
     if( components != gradientDirections )
     {
       isDiffusionWeightedImage = false;
     }
   }
 
   return isDiffusionWeightedImage;
 }
 
 const mitk::DiffusionPropertyHelper::BValueMapType & mitk::DiffusionPropertyHelper::GetBValueMap(const mitk::Image *image)
 {
   return dynamic_cast<mitk::BValueMapProperty *>(image->GetProperty(BVALUEMAPPROPERTYNAME.c_str()).GetPointer())->GetBValueMap();
 }
 
 float mitk::DiffusionPropertyHelper::GetReferenceBValue(const mitk::Image *image)
 {
    return dynamic_cast<mitk::FloatProperty *>(image->GetProperty(REFERENCEBVALUEPROPERTYNAME.c_str()).GetPointer())->GetValue();
 }
 
 const mitk::DiffusionPropertyHelper::MeasurementFrameType & mitk::DiffusionPropertyHelper::GetMeasurementFrame(const mitk::Image *image)
 {
   mitk::MeasurementFrameProperty::Pointer mf = dynamic_cast<mitk::MeasurementFrameProperty *>( image->GetProperty(MEASUREMENTFRAMEPROPERTYNAME.c_str()).GetPointer());
   if( mf.IsNull() )
   {
     //no measurement frame present, identity is assumed
     MeasurementFrameType identity;
     identity.set_identity();
     mf = mitk::MeasurementFrameProperty::New( identity );
   }
 
   return mf->GetMeasurementFrame();
 }
 
 mitk::DiffusionPropertyHelper::GradientDirectionsContainerType::Pointer mitk::DiffusionPropertyHelper::GetOriginalGradientContainer(const mitk::Image *image)
 {
   return dynamic_cast<mitk::GradientDirectionsProperty *>(image->GetProperty(ORIGINALGRADIENTCONTAINERPROPERTYNAME.c_str()).GetPointer())->GetGradientDirectionsContainer();
 }
 
 mitk::DiffusionPropertyHelper::GradientDirectionsContainerType::Pointer mitk::DiffusionPropertyHelper::GetGradientContainer(const mitk::Image *image)
 {
   return dynamic_cast<mitk::GradientDirectionsProperty *>(image->GetProperty(GRADIENTCONTAINERPROPERTYNAME.c_str()).GetPointer())->GetGradientDirectionsContainer();
 }
 
 bool mitk::DiffusionPropertyHelper::IsDiffusionWeightedImage() const
 {
   return IsDiffusionWeightedImage(m_Image);
 }
 
 const mitk::DiffusionPropertyHelper::BValueMapType &mitk::DiffusionPropertyHelper::GetBValueMap() const
 {
   return GetBValueMap(m_Image);
 }
 
 float mitk::DiffusionPropertyHelper::GetReferenceBValue() const
 {
   return GetReferenceBValue(m_Image);
 }
 
 const mitk::DiffusionPropertyHelper::MeasurementFrameType & mitk::DiffusionPropertyHelper::GetMeasurementFrame() const
 {
   return GetMeasurementFrame(m_Image);
 }
 
 mitk::DiffusionPropertyHelper::GradientDirectionsContainerType::Pointer mitk::DiffusionPropertyHelper::GetOriginalGradientContainer() const
 {
   return GetOriginalGradientContainer(m_Image);
 }
 
 mitk::DiffusionPropertyHelper::GradientDirectionsContainerType::Pointer mitk::DiffusionPropertyHelper::GetGradientContainer() const
 {
   return GetGradientContainer(m_Image);
 }
diff --git a/Modules/DiffusionImaging/DiffusionCore/Rendering/mitkOdfVtkMapper2D.txx b/Modules/DiffusionImaging/DiffusionCore/Rendering/mitkOdfVtkMapper2D.txx
index 91bb189c78..7565957134 100644
--- a/Modules/DiffusionImaging/DiffusionCore/Rendering/mitkOdfVtkMapper2D.txx
+++ b/Modules/DiffusionImaging/DiffusionCore/Rendering/mitkOdfVtkMapper2D.txx
@@ -1,882 +1,882 @@
 /*===================================================================
 
 The Medical Imaging Interaction Toolkit (MITK)
 
 Copyright (c) German Cancer Research Center,
 Division of Medical and Biological Informatics.
 All rights reserved.
 
 This software is distributed WITHOUT ANY WARRANTY; without
 even the implied warranty of MERCHANTABILITY or FITNESS FOR
 A PARTICULAR PURPOSE.
 
 See LICENSE.txt or http://www.mitk.org for details.
 
 ===================================================================*/
 
 
 #ifndef __mitkOdfVtkMapper2D_txx__
 #define __mitkOdfVtkMapper2D_txx__
 
 #include "mitkOdfVtkMapper2D.h"
 #include "mitkDataNode.h"
 #include "mitkBaseRenderer.h"
 #include "mitkMatrixConvert.h"
 #include "mitkGeometry3D.h"
 #include "mitkTimeGeometry.h"
 #include "mitkOdfNormalizationMethodProperty.h"
 #include "mitkOdfScaleByProperty.h"
 #include "mitkProperties.h"
 #include "mitkTensorImage.h"
 
 #include "vtkSphereSource.h"
 #include "vtkPropCollection.h"
 #include "vtkMaskedGlyph3D.h"
 #include "vtkGlyph2D.h"
 #include "vtkGlyph3D.h"
 #include "vtkMaskedProgrammableGlyphFilter.h"
 #include "vtkImageData.h"
 #include "vtkLinearTransform.h"
 #include "vtkCamera.h"
 #include "vtkPointData.h"
 #include "vtkTransformPolyDataFilter.h"
 #include "vtkTransform.h"
 #include "vtkOdfSource.h"
 #include "vtkDoubleArray.h"
 #include "vtkLookupTable.h"
 #include "vtkProperty.h"
 #include "vtkPolyDataNormals.h"
 #include "vtkLight.h"
 #include "vtkLightCollection.h"
 #include "vtkMath.h"
 #include "vtkFloatArray.h"
 #include "vtkDelaunay2D.h"
 #include "vtkMapper.h"
 
 #include "vtkRenderer.h"
 
 #include "itkOrientationDistributionFunction.h"
 
 #include "itkFixedArray.h"
 
 #include <mitkGL.h>
 #include "vtkOpenGLRenderer.h"
 
 #define _USE_MATH_DEFINES
 #include <math.h>
 
 template<class T, int N>
 vtkSmartPointer<vtkTransform> mitk::OdfVtkMapper2D<T,N>::m_OdfTransform = vtkSmartPointer<vtkTransform>::New();
 
 template<class T, int N>
 vtkSmartPointer<vtkOdfSource> mitk::OdfVtkMapper2D<T,N>::m_OdfSource = vtkSmartPointer<vtkOdfSource>::New();
 
 template<class T, int N>
 float mitk::OdfVtkMapper2D<T,N>::m_Scaling;
 
 template<class T, int N>
 int mitk::OdfVtkMapper2D<T,N>::m_Normalization;
 
 template<class T, int N>
 int mitk::OdfVtkMapper2D<T,N>::m_ScaleBy;
 
 template<class T, int N>
 float mitk::OdfVtkMapper2D<T,N>::m_IndexParam1;
 
 template<class T, int N>
 float mitk::OdfVtkMapper2D<T,N>::m_IndexParam2;
 
 #define ODF_MAPPER_PI M_PI
 
 
 template<class T, int N>
 mitk::OdfVtkMapper2D<T,N>::LocalStorage::LocalStorage()
 {
     m_PropAssemblies.push_back(vtkPropAssembly::New());
     m_PropAssemblies.push_back(vtkPropAssembly::New());
     m_PropAssemblies.push_back(vtkPropAssembly::New());
 
     m_OdfsPlanes.push_back(vtkAppendPolyData::New());
     m_OdfsPlanes.push_back(vtkAppendPolyData::New());
     m_OdfsPlanes.push_back(vtkAppendPolyData::New());
 
     m_OdfsPlanes[0]->AddInputData(vtkPolyData::New());
     m_OdfsPlanes[1]->AddInputData(vtkPolyData::New());
     m_OdfsPlanes[2]->AddInputData(vtkPolyData::New());
 
     m_OdfsActors.push_back(vtkActor::New());
     m_OdfsActors.push_back(vtkActor::New());
     m_OdfsActors.push_back(vtkActor::New());
 
     m_OdfsActors[0]->GetProperty()->SetInterpolationToGouraud();
     m_OdfsActors[1]->GetProperty()->SetInterpolationToGouraud();
     m_OdfsActors[2]->GetProperty()->SetInterpolationToGouraud();
 
     m_OdfsMappers.push_back(vtkPolyDataMapper::New());
     m_OdfsMappers.push_back(vtkPolyDataMapper::New());
     m_OdfsMappers.push_back(vtkPolyDataMapper::New());
 
     vtkLookupTable *lut = vtkLookupTable::New();
 
     m_OdfsMappers[0]->SetLookupTable(lut);
     m_OdfsMappers[1]->SetLookupTable(lut);
     m_OdfsMappers[2]->SetLookupTable(lut);
 
     m_OdfsActors[0]->SetMapper(m_OdfsMappers[0]);
     m_OdfsActors[1]->SetMapper(m_OdfsMappers[1]);
     m_OdfsActors[2]->SetMapper(m_OdfsMappers[2]);
 }
 
 template<class T, int N>
 mitk::OdfVtkMapper2D<T,N>
 ::OdfVtkMapper2D()
 {
 
     m_Planes.push_back(vtkPlane::New());
     m_Planes.push_back(vtkPlane::New());
     m_Planes.push_back(vtkPlane::New());
 
     m_Cutters.push_back(vtkCutter::New());
     m_Cutters.push_back(vtkCutter::New());
     m_Cutters.push_back(vtkCutter::New());
 
     m_Cutters[0]->SetCutFunction( m_Planes[0] );
     m_Cutters[0]->GenerateValues( 1, 0, 1 );
 
     m_Cutters[1]->SetCutFunction( m_Planes[1] );
     m_Cutters[1]->GenerateValues( 1, 0, 1 );
 
     m_Cutters[2]->SetCutFunction( m_Planes[2] );
     m_Cutters[2]->GenerateValues( 1, 0, 1 );
 
     // Windowing the cutted planes in direction 1
     m_ThickPlanes1.push_back(vtkThickPlane::New());
     m_ThickPlanes1.push_back(vtkThickPlane::New());
     m_ThickPlanes1.push_back(vtkThickPlane::New());
 
     m_Clippers1.push_back(vtkClipPolyData::New());
     m_Clippers1.push_back(vtkClipPolyData::New());
     m_Clippers1.push_back(vtkClipPolyData::New());
 
     m_Clippers1[0]->SetClipFunction( m_ThickPlanes1[0] );
     m_Clippers1[1]->SetClipFunction( m_ThickPlanes1[1] );
     m_Clippers1[2]->SetClipFunction( m_ThickPlanes1[2] );
 
     // Windowing the cutted planes in direction 2
     m_ThickPlanes2.push_back(vtkThickPlane::New());
     m_ThickPlanes2.push_back(vtkThickPlane::New());
     m_ThickPlanes2.push_back(vtkThickPlane::New());
 
     m_Clippers2.push_back(vtkClipPolyData::New());
     m_Clippers2.push_back(vtkClipPolyData::New());
     m_Clippers2.push_back(vtkClipPolyData::New());
 
     m_Clippers2[0]->SetClipFunction( m_ThickPlanes2[0] );
     m_Clippers2[1]->SetClipFunction( m_ThickPlanes2[1] );
     m_Clippers2[2]->SetClipFunction( m_ThickPlanes2[2] );
 
     m_ShowMaxNumber = 500;
 }
 
 template<class T, int N>
 mitk::OdfVtkMapper2D<T,N>
 ::~OdfVtkMapper2D()
 {
 
 }
 
 template<class T, int N>
 mitk::Image* mitk::OdfVtkMapper2D<T,N>
 ::GetInput()
 {
     return static_cast<mitk::Image * > ( m_DataNode->GetData() );
 }
 
 template<class T, int N>
 vtkProp*  mitk::OdfVtkMapper2D<T,N>
 ::GetVtkProp(mitk::BaseRenderer* renderer)
 {
     LocalStorage *localStorage = m_LSH.GetLocalStorage(renderer);
     return localStorage->m_PropAssemblies[GetIndex(renderer)];
 }
 
 template<class T, int N>
 int  mitk::OdfVtkMapper2D<T,N>
 ::GetIndex(mitk::BaseRenderer* renderer)
 {
     if(!strcmp(renderer->GetName(),"stdmulti.widget1"))
         return 0;
 
     if(!strcmp(renderer->GetName(),"stdmulti.widget2"))
         return 1;
 
     if(!strcmp(renderer->GetName(),"stdmulti.widget3"))
         return 2;
 
     return 0;
 }
 
 template<class T, int N>
 void  mitk::OdfVtkMapper2D<T,N>
 ::GlyphMethod(void *arg)
 {
     vtkMaskedProgrammableGlyphFilter* pfilter=(vtkMaskedProgrammableGlyphFilter*)arg;
 
     double point[3];
     double debugpoint[3];
     pfilter->GetPoint(point);
     pfilter->GetPoint(debugpoint);
 
     itk::Point<double,3> p(point);
     Vector3D spacing = pfilter->GetGeometry()->GetSpacing();
     p[0] /= spacing[0];
     p[1] /= spacing[1];
     p[2] /= spacing[2];
 
     mitk::Point3D p2;
     pfilter->GetGeometry()->IndexToWorld( p, p2 );
     point[0] = p2[0];
     point[1] = p2[1];
     point[2] = p2[2];
 
     vtkPointData* data = pfilter->GetPointData();
     vtkDataArray* odfvals = data->GetArray("vector");
     vtkIdType id = pfilter->GetPointId();
     m_OdfTransform->Identity();
     m_OdfTransform->Translate(point[0],point[1],point[2]);
 
     typedef itk::OrientationDistributionFunction<float,N> OdfType;
     OdfType odf;
 
     if(odfvals->GetNumberOfComponents()==6)
     {
         float tensorelems[6] = {
             (float)odfvals->GetComponent(id,0),
             (float)odfvals->GetComponent(id,1),
             (float)odfvals->GetComponent(id,2),
             (float)odfvals->GetComponent(id,3),
             (float)odfvals->GetComponent(id,4),
             (float)odfvals->GetComponent(id,5),
         };
         itk::DiffusionTensor3D<float> tensor(tensorelems);
         odf.InitFromTensor(tensor);
     }
     else
     {
         for(int i=0; i<N; i++)
             odf[i] = (double)odfvals->GetComponent(id,i);
     }
 
     switch(m_ScaleBy)
     {
     case ODFSB_NONE:
         m_OdfSource->SetScale(m_Scaling);
         break;
     case ODFSB_GFA:
         m_OdfSource->SetScale(m_Scaling*odf.GetGeneralizedGFA(m_IndexParam1, m_IndexParam2));
         break;
     case ODFSB_PC:
         m_OdfSource->SetScale(m_Scaling*odf.GetPrincipleCurvature(m_IndexParam1, m_IndexParam2, 0));
         break;
     }
 
     m_OdfSource->SetNormalization(m_Normalization);
     m_OdfSource->SetOdf(odf);
     m_OdfSource->Modified();
 }
 
 template<class T, int N>
 typename mitk::OdfVtkMapper2D<T,N>::OdfDisplayGeometry mitk::OdfVtkMapper2D<T,N>
 ::MeasureDisplayedGeometry(mitk::BaseRenderer* renderer)
 {
     PlaneGeometry::ConstPointer worldPlaneGeometry = renderer->GetCurrentWorldPlaneGeometry();
 
     // set up the cutter orientation according to the current geometry of
     // the renderers plane
     double vp[ 3 ], vnormal[ 3 ];
     Point3D point = worldPlaneGeometry->GetOrigin();
     Vector3D normal = worldPlaneGeometry->GetNormal(); normal.Normalize();
     vnl2vtk( point.GetVnlVector(), vp );
     vnl2vtk( normal.GetVnlVector(), vnormal );
 
     mitk::DisplayGeometry::Pointer dispGeometry = renderer->GetDisplayGeometry();
     mitk::Vector2D size = dispGeometry->GetSizeInMM();
     mitk::Vector2D origin = dispGeometry->GetOriginInMM();
 
     //
     //  |------O------|
     //  |      d2     |
     //  L  d1  M      |
     //  |             |
     //  |-------------|
     //
 
     mitk::Vector2D M;
     mitk::Vector2D L;
     mitk::Vector2D O;
 
     M[0] = origin[0] + size[0]/2;
     M[1] = origin[1] + size[1]/2;
 
     L[0] = origin[0];
     L[1] = origin[1] + size[1]/2;
 
     O[0] = origin[0] + size[0]/2;
     O[1] = origin[1] + size[1];
 
     mitk::Point2D point1;
     point1[0] = M[0]; point1[1] = M[1];
     mitk::Point3D M3D;
     dispGeometry->Map(point1, M3D);
 
     point1[0] = L[0]; point1[1] = L[1];
     mitk::Point3D L3D;
     dispGeometry->Map(point1, L3D);
 
     point1[0] = O[0]; point1[1] = O[1];
     mitk::Point3D O3D;
     dispGeometry->Map(point1, O3D);
 
     double d1 = sqrt((M3D[0]-L3D[0])*(M3D[0]-L3D[0])
                      + (M3D[1]-L3D[1])*(M3D[1]-L3D[1])
                      + (M3D[2]-L3D[2])*(M3D[2]-L3D[2]));
     double d2 = sqrt((M3D[0]-O3D[0])*(M3D[0]-O3D[0])
                      + (M3D[1]-O3D[1])*(M3D[1]-O3D[1])
                      + (M3D[2]-O3D[2])*(M3D[2]-O3D[2]));
     double d = d1>d2 ? d1 : d2;
     d = d2;
 
     OdfDisplayGeometry retval;
     retval.vp[0] = vp[0];
     retval.vp[1] = vp[1];
     retval.vp[2] = vp[2];
     retval.vnormal[0] = vnormal[0];
     retval.vnormal[1] = vnormal[1];
     retval.vnormal[2] = vnormal[2];
     retval.normal[0] = normal[0];
     retval.normal[1] = normal[1];
     retval.normal[2] = normal[2];
     retval.d = d;
     retval.d1 = d1;
     retval.d2 = d2;
     retval.M3D[0] = M3D[0];
     retval.M3D[1] = M3D[1];
     retval.M3D[2] = M3D[2];
     retval.L3D[0] = L3D[0];
     retval.L3D[1] = L3D[1];
     retval.L3D[2] = L3D[2];
     retval.O3D[0] = O3D[0];
     retval.O3D[1] = O3D[1];
     retval.O3D[2] = O3D[2];
 
     retval.vp_original[0] = vp[0];
     retval.vp_original[1] = vp[1];
     retval.vp_original[2] = vp[2];
     retval.vnormal_original[0] = vnormal[0];
     retval.vnormal_original[1] = vnormal[1];
     retval.vnormal_original[2] = vnormal[2];
     retval.size[0] = size[0];
     retval.size[1] = size[1];
     retval.origin[0] = origin[0];
     retval.origin[1] = origin[1];
 
     return retval;
 }
 
 template<class T, int N>
 void  mitk::OdfVtkMapper2D<T,N>
 ::Slice(mitk::BaseRenderer* renderer, OdfDisplayGeometry dispGeo)
 {
     LocalStorage *localStorage = m_LSH.GetLocalStorage(renderer);
 
     vtkLinearTransform * vtktransform =
             this->GetDataNode()->GetVtkTransform(this->GetTimestep());
 
     int index = GetIndex(renderer);
 
     vtkSmartPointer<vtkTransform> inversetransform = vtkSmartPointer<vtkTransform>::New();
     inversetransform->Identity();
     inversetransform->Concatenate(vtktransform->GetLinearInverse());
     double myscale[3];
     ((vtkTransform*)vtktransform)->GetScale(myscale);
     inversetransform->PostMultiply();
     inversetransform->Scale(1*myscale[0],1*myscale[1],1*myscale[2]);
     inversetransform->TransformPoint( dispGeo.vp, dispGeo.vp );
     inversetransform->TransformNormalAtPoint( dispGeo.vp, dispGeo.vnormal, dispGeo.vnormal );
 
     // vtk works in axis align coords
     // thus the normal also must be axis align, since
     // we do not allow arbitrary cutting through volume
     //
     // vnormal should already be axis align, but in order
     // to get rid of precision effects, we set the two smaller
     // components to zero here
     int dims[3];
     m_VtkImage->GetDimensions(dims);
     double spac[3];
     m_VtkImage->GetSpacing(spac);
     if(fabs(dispGeo.vnormal[0]) > fabs(dispGeo.vnormal[1])
             && fabs(dispGeo.vnormal[0]) > fabs(dispGeo.vnormal[2]) )
     {
         if(fabs(dispGeo.vp[0]/spac[0]) < 0.4)
             dispGeo.vp[0] = 0.4*spac[0];
         if(fabs(dispGeo.vp[0]/spac[0]) > (dims[0]-1)-0.4)
             dispGeo.vp[0] = ((dims[0]-1)-0.4)*spac[0];
         dispGeo.vnormal[1] = 0;
         dispGeo.vnormal[2] = 0;
     }
 
     if(fabs(dispGeo.vnormal[1]) > fabs(dispGeo.vnormal[0]) && fabs(dispGeo.vnormal[1]) > fabs(dispGeo.vnormal[2]) )
     {
         if(fabs(dispGeo.vp[1]/spac[1]) < 0.4)
             dispGeo.vp[1] = 0.4*spac[1];
         if(fabs(dispGeo.vp[1]/spac[1]) > (dims[1]-1)-0.4)
             dispGeo.vp[1] = ((dims[1]-1)-0.4)*spac[1];
         dispGeo.vnormal[0] = 0;
         dispGeo.vnormal[2] = 0;
     }
 
     if(fabs(dispGeo.vnormal[2]) > fabs(dispGeo.vnormal[1]) && fabs(dispGeo.vnormal[2]) > fabs(dispGeo.vnormal[0]) )
     {
         if(fabs(dispGeo.vp[2]/spac[2]) < 0.4)
             dispGeo.vp[2] = 0.4*spac[2];
         if(fabs(dispGeo.vp[2]/spac[2]) > (dims[2]-1)-0.4)
             dispGeo.vp[2] = ((dims[2]-1)-0.4)*spac[2];
         dispGeo.vnormal[0] = 0;
         dispGeo.vnormal[1] = 0;
     }
 
 
     m_Planes[index]->SetTransform( (vtkAbstractTransform*)NULL );
     m_Planes[index]->SetOrigin( dispGeo.vp );
     m_Planes[index]->SetNormal( dispGeo.vnormal );
 
     vtkSmartPointer<vtkPoints> points;
     vtkSmartPointer<vtkPoints> tmppoints;
     vtkSmartPointer<vtkPolyData> polydata;
     vtkSmartPointer<vtkFloatArray> pointdata;
     vtkSmartPointer<vtkDelaunay2D> delaunay;
     vtkSmartPointer<vtkPolyData> cuttedPlane;
 
     // the cutter only works if we do not have a 2D-image
     // or if we have a 2D-image and want to see the whole image.
     //
     // for side views of 2D-images, we need some special treatment
     if(!( (dims[0] == 1 && dispGeo.vnormal[0] != 0) ||
           (dims[1] == 1 && dispGeo.vnormal[1] != 0) ||
           (dims[2] == 1 && dispGeo.vnormal[2] != 0) ))
     {
         m_Cutters[index]->SetCutFunction( m_Planes[index] );
         m_Cutters[index]->SetInputData( m_VtkImage );
         m_Cutters[index]->Update();
         cuttedPlane = m_Cutters[index]->GetOutput();
     }
     else
     {
         // cutting of a 2D-Volume does not work,
         // so we have to build up our own polydata object
         cuttedPlane = vtkPolyData::New();
         points = vtkPoints::New();
         points->SetNumberOfPoints(m_VtkImage->GetNumberOfPoints());
         for(int i=0; i<m_VtkImage->GetNumberOfPoints(); i++)
         {
             points->SetPoint(i, m_VtkImage->GetPoint(i));
         }
         cuttedPlane->SetPoints(points);
 
         pointdata = vtkFloatArray::New();
         int comps  = m_VtkImage->GetPointData()->GetScalars()->GetNumberOfComponents();
         pointdata->SetNumberOfComponents(comps);
         int tuples = m_VtkImage->GetPointData()->GetScalars()->GetNumberOfTuples();
         pointdata->SetNumberOfTuples(tuples);
         for(int i=0; i<tuples; i++)
             pointdata->SetTuple(i,m_VtkImage->GetPointData()->GetScalars()->GetTuple(i));
         pointdata->SetName( "vector" );
         cuttedPlane->GetPointData()->AddArray(pointdata);
 
         int nZero1, nZero2;
         if(dims[0]==1)
         {
             nZero1 = 1; nZero2 = 2;
         }
         else if(dims[1]==1)
         {
             nZero1 = 0; nZero2 = 2;
         }
         else
         {
             nZero1 = 0; nZero2 = 1;
         }
 
         tmppoints = vtkPoints::New();
         for(int j=0; j<m_VtkImage->GetNumberOfPoints(); j++){
             double pt[3];
             m_VtkImage->GetPoint(j,pt);
             tmppoints->InsertNextPoint(pt[nZero1],pt[nZero2],0);
         }
 
         polydata = vtkPolyData::New();
         polydata->SetPoints( tmppoints );
         delaunay = vtkDelaunay2D::New();
         delaunay->SetInputData( polydata );
         delaunay->Update();
         vtkCellArray* polys = delaunay->GetOutput()->GetPolys();
         cuttedPlane->SetPolys(polys);
     }
 
     if(cuttedPlane->GetNumberOfPoints())
     {
         //  WINDOWING HERE
         inversetransform = vtkTransform::New();
         inversetransform->Identity();
         inversetransform->Concatenate(vtktransform->GetLinearInverse());
         double myscale[3];
         ((vtkTransform*)vtktransform)->GetScale(myscale);
         inversetransform->PostMultiply();
         inversetransform->Scale(1*myscale[0],1*myscale[1],1*myscale[2]);
 
         dispGeo.vnormal[0] = dispGeo.M3D[0]-dispGeo.O3D[0];
         dispGeo.vnormal[1] = dispGeo.M3D[1]-dispGeo.O3D[1];
         dispGeo.vnormal[2] = dispGeo.M3D[2]-dispGeo.O3D[2];
         vtkMath::Normalize(dispGeo.vnormal);
         dispGeo.vp[0] = dispGeo.M3D[0];
         dispGeo.vp[1] = dispGeo.M3D[1];
         dispGeo.vp[2] = dispGeo.M3D[2];
 
         inversetransform->TransformPoint( dispGeo.vp, dispGeo.vp );
         inversetransform->TransformNormalAtPoint( dispGeo.vp, dispGeo.vnormal, dispGeo.vnormal );
 
         m_ThickPlanes1[index]->count = 0;
         m_ThickPlanes1[index]->SetTransform((vtkAbstractTransform*)NULL );
         m_ThickPlanes1[index]->SetPose( dispGeo.vnormal, dispGeo.vp );
         m_ThickPlanes1[index]->SetThickness(dispGeo.d2);
         m_Clippers1[index]->SetClipFunction( m_ThickPlanes1[index] );
         m_Clippers1[index]->SetInputData( cuttedPlane );
         m_Clippers1[index]->SetInsideOut(1);
         m_Clippers1[index]->Update();
 
         dispGeo.vnormal[0] = dispGeo.M3D[0]-dispGeo.L3D[0];
         dispGeo.vnormal[1] = dispGeo.M3D[1]-dispGeo.L3D[1];
         dispGeo.vnormal[2] = dispGeo.M3D[2]-dispGeo.L3D[2];
         vtkMath::Normalize(dispGeo.vnormal);
         dispGeo.vp[0] = dispGeo.M3D[0];
         dispGeo.vp[1] = dispGeo.M3D[1];
         dispGeo.vp[2] = dispGeo.M3D[2];
 
         inversetransform->TransformPoint( dispGeo.vp, dispGeo.vp );
         inversetransform->TransformNormalAtPoint( dispGeo.vp, dispGeo.vnormal, dispGeo.vnormal );
 
         m_ThickPlanes2[index]->count = 0;
         m_ThickPlanes2[index]->SetTransform((vtkAbstractTransform*)NULL );
         m_ThickPlanes2[index]->SetPose( dispGeo.vnormal, dispGeo.vp );
         m_ThickPlanes2[index]->SetThickness(dispGeo.d1);
         m_Clippers2[index]->SetClipFunction( m_ThickPlanes2[index] );
         m_Clippers2[index]->SetInputData( m_Clippers1[index]->GetOutput() );
         m_Clippers2[index]->SetInsideOut(1);
         m_Clippers2[index]->Update();
 
         cuttedPlane = m_Clippers2[index]->GetOutput ();
 
         if(cuttedPlane->GetNumberOfPoints())
         {
             localStorage->m_OdfsPlanes[index]->RemoveAllInputs();
 
             vtkSmartPointer<vtkPolyDataNormals> normals = vtkSmartPointer<vtkPolyDataNormals>::New();
             normals->SetInputConnection( m_OdfSource->GetOutputPort() );
             normals->SplittingOff();
             normals->ConsistencyOff();
             normals->AutoOrientNormalsOff();
             normals->ComputePointNormalsOn();
             normals->ComputeCellNormalsOff();
             normals->FlipNormalsOff();
             normals->NonManifoldTraversalOff();
 
             vtkSmartPointer<vtkTransformPolyDataFilter> trans = vtkSmartPointer<vtkTransformPolyDataFilter>::New();
             trans->SetInputConnection( normals->GetOutputPort() );
             trans->SetTransform(m_OdfTransform);
 
             vtkSmartPointer<vtkMaskedProgrammableGlyphFilter> glyphGenerator = vtkSmartPointer<vtkMaskedProgrammableGlyphFilter>::New();
             glyphGenerator->SetMaximumNumberOfPoints(std::min(m_ShowMaxNumber,(int)cuttedPlane->GetNumberOfPoints()));
-            glyphGenerator->SetRandomMode(0);
+            glyphGenerator->SetRandomMode(1);
             glyphGenerator->SetUseMaskPoints(1);
             glyphGenerator->SetSourceConnection(trans->GetOutputPort() );
             glyphGenerator->SetInput(cuttedPlane);
             glyphGenerator->SetColorModeToColorBySource();
             glyphGenerator->SetInputArrayToProcess(0,0,0, vtkDataObject::FIELD_ASSOCIATION_POINTS , "vector");
             glyphGenerator->SetGeometry(this->GetDataNode()->GetData()->GetGeometry());
             glyphGenerator->SetGlyphMethod(&(GlyphMethod),(void *)glyphGenerator);
 
             try
             {
                 glyphGenerator->Update();
             }
             catch( itk::ExceptionObject& err )
             {
                 std::cout << err << std::endl;
             }
 
             localStorage->m_OdfsPlanes[index]->AddInputConnection(glyphGenerator->GetOutputPort());
 
             localStorage->m_OdfsPlanes[index]->Update();
         }
     }
     localStorage->m_PropAssemblies[index]->VisibilityOn();
     if(localStorage->m_PropAssemblies[index]->GetParts()->IsItemPresent(localStorage->m_OdfsActors[index]))
         localStorage->m_PropAssemblies[index]->RemovePart(localStorage->m_OdfsActors[index]);
     localStorage->m_OdfsMappers[index]->SetInputData(localStorage->m_OdfsPlanes[index]->GetOutput());
     localStorage->m_PropAssemblies[index]->AddPart(localStorage->m_OdfsActors[index]);
 }
 
 template<class T, int N>
 bool mitk::OdfVtkMapper2D<T,N>
 ::IsVisibleOdfs(mitk::BaseRenderer* renderer)
 {
     mitk::Image::Pointer input  = const_cast<mitk::Image*>(this->GetInput());
     const TimeGeometry *inputTimeGeometry = input->GetTimeGeometry();
     if(inputTimeGeometry==NULL || inputTimeGeometry->CountTimeSteps()==0 || !inputTimeGeometry->IsValidTimeStep(this->GetTimestep()))
         return false;
 
     if(this->IsPlaneRotated(renderer))
         return false;
 
     bool retval = false;
     switch(GetIndex(renderer))
     {
     case 0:
         GetDataNode()->GetVisibility(retval, renderer, "VisibleOdfs_T");
         break;
     case 1:
         GetDataNode()->GetVisibility(retval, renderer, "VisibleOdfs_S");
         break;
     case 2:
         GetDataNode()->GetVisibility(retval, renderer, "VisibleOdfs_C");
         break;
     }
 
     return retval;
 }
 
 template<class T, int N>
 void  mitk::OdfVtkMapper2D<T,N>
 ::MitkRenderOverlay(mitk::BaseRenderer* renderer)
 {
     if ( this->IsVisibleOdfs(renderer)==false )
         return;
 
     if ( this->GetVtkProp(renderer)->GetVisibility() )
         this->GetVtkProp(renderer)->RenderOverlay(renderer->GetVtkRenderer());
 }
 
 template<class T, int N>
 void  mitk::OdfVtkMapper2D<T,N>
 ::MitkRenderOpaqueGeometry(mitk::BaseRenderer* renderer)
 {
     if ( this->IsVisibleOdfs( renderer )==false )
         return;
 
     if ( this->GetVtkProp(renderer)->GetVisibility() )
     {
         // adapt cam pos
         this->GetVtkProp(renderer)->RenderOpaqueGeometry( renderer->GetVtkRenderer() );
     }
 }
 
 template<class T, int N>
 void  mitk::OdfVtkMapper2D<T,N>
 ::MitkRenderTranslucentGeometry(mitk::BaseRenderer* renderer)
 {
     if ( this->IsVisibleOdfs(renderer)==false )
         return;
 
     if ( this->GetVtkProp(renderer)->GetVisibility() )
         this->GetVtkProp(renderer)->RenderTranslucentPolygonalGeometry(renderer->GetVtkRenderer());
 
 }
 
 template<class T, int N>
 void mitk::OdfVtkMapper2D<T,N>
 ::Update(mitk::BaseRenderer* renderer)
 {
     bool visible = true;
     GetDataNode()->GetVisibility(visible, renderer, "visible");
 
     if ( !visible ) return;
 
     mitk::Image::Pointer input = const_cast<mitk::Image*>( this->GetInput() );
     if ( input.IsNull() ) return ;
 
     std::string classname("TensorImage");
     if(classname.compare(input->GetNameOfClass())==0)
         m_VtkImage = dynamic_cast<mitk::TensorImage*>( this->GetInput() )->GetNonRgbVtkImageData();
 
     std::string qclassname("QBallImage");
     if(qclassname.compare(input->GetNameOfClass())==0)
         m_VtkImage = dynamic_cast<mitk::QBallImage*>( this->GetInput() )->GetNonRgbVtkImageData();
 
     if( m_VtkImage )
     {
         // make sure, that we have point data with more than 1 component (as vectors)
         vtkPointData* pointData = m_VtkImage->GetPointData();
         if ( pointData == NULL )
         {
             itkWarningMacro( << "m_VtkImage->GetPointData() returns NULL!" );
             return ;
         }
         if ( pointData->GetNumberOfArrays() == 0 )
         {
             itkWarningMacro( << "m_VtkImage->GetPointData()->GetNumberOfArrays() is 0!" );
             return ;
         }
         else if ( pointData->GetArray(0)->GetNumberOfComponents() != N
                   && pointData->GetArray(0)->GetNumberOfComponents() != 6 /*for tensor visualization*/)
         {
             itkWarningMacro( << "number of components != number of directions in ODF!" );
             return;
         }
         else if ( pointData->GetArrayName( 0 ) == NULL )
         {
             m_VtkImage->GetPointData()->GetArray(0)->SetName("vector");
         }
 
         GenerateDataForRenderer(renderer);
     }
     else
     {
         itkWarningMacro( << "m_VtkImage is NULL!" );
         return ;
     }
 }
 
 template<class T, int N>
 void  mitk::OdfVtkMapper2D<T,N>
 ::GenerateDataForRenderer( mitk::BaseRenderer *renderer )
 {
     LocalStorage *localStorage = m_LSH.GetLocalStorage(renderer);
 
     OdfDisplayGeometry dispGeo = MeasureDisplayedGeometry( renderer);
 
 
     if ( (localStorage->m_LastUpdateTime >= m_DataNode->GetMTime()) //was the node modified?
       && (localStorage->m_LastUpdateTime >= m_DataNode->GetPropertyList()->GetMTime()) //was a property modified?
       && (localStorage->m_LastUpdateTime >= m_DataNode->GetPropertyList(renderer)->GetMTime())
       && dispGeo.Equals(m_LastDisplayGeometry))
         return;
 
     localStorage->m_LastUpdateTime.Modified();
 
     if(!IsVisibleOdfs(renderer))
     {
         localStorage->m_OdfsActors[0]->VisibilityOff();
         localStorage->m_OdfsActors[1]->VisibilityOff();
         localStorage->m_OdfsActors[2]->VisibilityOff();
     }
     else
     {
         localStorage->m_OdfsActors[0]->VisibilityOn();
         localStorage->m_OdfsActors[1]->VisibilityOn();
         localStorage->m_OdfsActors[2]->VisibilityOn();
 
         m_OdfSource->SetAdditionalScale(GetMinImageSpacing(GetIndex(renderer)));
         ApplyPropertySettings();
         Slice(renderer, dispGeo);
         m_LastDisplayGeometry = dispGeo;
     }
 }
 
 template<class T, int N>
 double  mitk::OdfVtkMapper2D<T,N>::GetMinImageSpacing( int index )
 {
     // Spacing adapted scaling
     double spacing[3];
     m_VtkImage->GetSpacing(spacing);
     double min = spacing[0];
     if(index==0)
     {
         min = spacing[0];
         min = min > spacing[1] ? spacing[1] : min;
     }
     if(index==1)
     {
         min = spacing[1];
         min = min > spacing[2] ? spacing[2] : min;
     }
     if(index==2)
     {
         min = spacing[0];
         min = min > spacing[2] ? spacing[2] : min;
     }
     return min;
 }
 
 template<class T, int N>
 void  mitk::OdfVtkMapper2D<T,N>
 ::ApplyPropertySettings()
 {
     this->GetDataNode()->GetFloatProperty( "Scaling", m_Scaling );
     this->GetDataNode()->GetIntProperty( "ShowMaxNumber", m_ShowMaxNumber );
 
     OdfNormalizationMethodProperty* nmp = dynamic_cast<OdfNormalizationMethodProperty*>(this->GetDataNode()->GetProperty( "Normalization" ));
     if(nmp)
         m_Normalization = nmp->GetNormalization();
 
     OdfScaleByProperty* sbp = dynamic_cast<OdfScaleByProperty*>(this->GetDataNode()->GetProperty( "ScaleBy" ));
     if(sbp)
         m_ScaleBy = sbp->GetScaleBy();
 
     this->GetDataNode()->GetFloatProperty( "IndexParam1", m_IndexParam1);
     this->GetDataNode()->GetFloatProperty( "IndexParam2", m_IndexParam2);
 }
 
 template <class T, int N>
 bool mitk::OdfVtkMapper2D<T,N>
 ::IsPlaneRotated(mitk::BaseRenderer* renderer)
 {
     PlaneGeometry::ConstPointer worldPlaneGeometry = renderer->GetCurrentWorldPlaneGeometry();
 
     double vnormal[ 3 ];
     Vector3D normal = worldPlaneGeometry->GetNormal(); normal.Normalize();
     vnl2vtk( normal.GetVnlVector(), vnormal );
 
     mitk::Image* currentImage = dynamic_cast<mitk::Image* >( this->GetDataNode()->GetData() );
     if( currentImage == NULL )
         return false;
     mitk::Vector3D imageNormal0 = currentImage->GetSlicedGeometry()->GetAxisVector(0);
     mitk::Vector3D imageNormal1 = currentImage->GetSlicedGeometry()->GetAxisVector(1);
     mitk::Vector3D imageNormal2 = currentImage->GetSlicedGeometry()->GetAxisVector(2);
     imageNormal0.Normalize();
     imageNormal1.Normalize();
     imageNormal2.Normalize();
 
     double eps = 0.000001;
     int test = 0;
     if( fabs(fabs(dot_product(normal.GetVnlVector(),imageNormal0.GetVnlVector()))-1) > eps )
         test++;
     if( fabs(fabs(dot_product(normal.GetVnlVector(),imageNormal1.GetVnlVector()))-1) > eps )
         test++;
     if( fabs(fabs(dot_product(normal.GetVnlVector(),imageNormal2.GetVnlVector()))-1) > eps )
         test++;
     if (test==3)
         return true;
     return false;
 }
 
 template<class T, int N>
 void  mitk::OdfVtkMapper2D<T,N>
 ::SetDefaultProperties(mitk::DataNode* node, mitk::BaseRenderer*  /*renderer*/, bool  /*overwrite*/)
 {
     node->SetProperty( "ShowMaxNumber", mitk::IntProperty::New( 150 ) );
     node->SetProperty( "Scaling", mitk::FloatProperty::New( 1.0 ) );
     node->SetProperty( "Normalization", mitk::OdfNormalizationMethodProperty::New());
     node->SetProperty( "ScaleBy", mitk::OdfScaleByProperty::New());
     node->SetProperty( "IndexParam1", mitk::FloatProperty::New(2));
     node->SetProperty( "IndexParam2", mitk::FloatProperty::New(1));
     node->SetProperty( "visible", mitk::BoolProperty::New( true ) );
     node->SetProperty( "VisibleOdfs_T", mitk::BoolProperty::New( false ) );
     node->SetProperty( "VisibleOdfs_C", mitk::BoolProperty::New( false ) );
     node->SetProperty( "VisibleOdfs_S", mitk::BoolProperty::New( false ) );
     node->SetProperty ("layer", mitk::IntProperty::New(100));
     node->SetProperty( "DoRefresh", mitk::BoolProperty::New( true ) );
 }
 
 #endif // __mitkOdfVtkMapper2D_txx__
 
diff --git a/Modules/DiffusionImaging/FiberTracking/Algorithms/itkTractDensityImageFilter.cpp b/Modules/DiffusionImaging/FiberTracking/Algorithms/itkTractDensityImageFilter.cpp
index 13df693a5d..7b6aaf59f0 100644
--- a/Modules/DiffusionImaging/FiberTracking/Algorithms/itkTractDensityImageFilter.cpp
+++ b/Modules/DiffusionImaging/FiberTracking/Algorithms/itkTractDensityImageFilter.cpp
@@ -1,248 +1,211 @@
 /*===================================================================
 
 The Medical Imaging Interaction Toolkit (MITK)
 
 Coindex[1]right (c) German Cancer Research Center,
 Division of Medical and Biological Informatics.
 All rights reserved.
 
 This software is distributed WITHOUT ANY WARRANTY; without
 even the implied warranty of MERCHANTABILITY or FITNESS FOR
 A PARTICULAR PURPOSE.
 
 See LICENSE.txt or http://www.mitk.org for details.
 
 ===================================================================*/
 #include "itkTractDensityImageFilter.h"
 
 // VTK
 #include <vtkPolyLine.h>
 #include <vtkCellArray.h>
 #include <vtkCellData.h>
 #include <vtkCell.h>
 
 // misc
 #include <math.h>
 #include <boost/progress.hpp>
 
 namespace itk{
 
 template< class OutputImageType >
 TractDensityImageFilter< OutputImageType >::TractDensityImageFilter()
     : m_InvertImage(false)
     , m_FiberBundle(NULL)
     , m_UpsamplingFactor(1)
     , m_InputImage(NULL)
     , m_BinaryOutput(false)
     , m_UseImageGeometry(false)
     , m_OutputAbsoluteValues(false)
     , m_UseTrilinearInterpolation(false)
     , m_DoFiberResampling(true)
 {
 
 }
 
 template< class OutputImageType >
 TractDensityImageFilter< OutputImageType >::~TractDensityImageFilter()
 {
 }
 
 template< class OutputImageType >
 itk::Point<float, 3> TractDensityImageFilter< OutputImageType >::GetItkPoint(double point[3])
 {
     itk::Point<float, 3> itkPoint;
     itkPoint[0] = point[0];
     itkPoint[1] = point[1];
     itkPoint[2] = point[2];
     return itkPoint;
 }
 
 template< class OutputImageType >
 void TractDensityImageFilter< OutputImageType >::GenerateData()
 {
     // generate upsampled image
-    mitk::BaseGeometry::Pointer geometry = m_FiberBundle->GetGeometry();
     typename OutputImageType::Pointer outImage = this->GetOutput();
+    if (fibs.empty() && m_FiberBundle.IsNotNull())
+        fibs.push_back(m_FiberBundle);
 
     // calculate new image parameters
     itk::Vector<double,3> newSpacing;
     mitk::Point3D newOrigin;
     itk::Matrix<double, 3, 3> newDirection;
     ImageRegion<3> upsampledRegion;
     if (m_UseImageGeometry && !m_InputImage.IsNull())
     {
         MITK_INFO << "TractDensityImageFilter: using image geometry";
         newSpacing = m_InputImage->GetSpacing()/m_UpsamplingFactor;
         upsampledRegion = m_InputImage->GetLargestPossibleRegion();
         newOrigin = m_InputImage->GetOrigin();
         typename OutputImageType::RegionType::SizeType size = upsampledRegion.GetSize();
         size[0] *= m_UpsamplingFactor;
         size[1] *= m_UpsamplingFactor;
         size[2] *= m_UpsamplingFactor;
         upsampledRegion.SetSize(size);
         newDirection = m_InputImage->GetDirection();
     }
     else
     {
         MITK_INFO << "TractDensityImageFilter: using fiber bundle geometry";
+        mitk::BaseGeometry::Pointer geometry = m_FiberBundle->GetGeometry();
         newSpacing = geometry->GetSpacing()/m_UpsamplingFactor;
         newOrigin = geometry->GetOrigin();
         mitk::Geometry3D::BoundsArrayType bounds = geometry->GetBounds();
         newOrigin[0] += bounds.GetElement(0);
         newOrigin[1] += bounds.GetElement(2);
         newOrigin[2] += bounds.GetElement(4);
 
         for (int i=0; i<3; i++)
             for (int j=0; j<3; j++)
                 newDirection[j][i] = geometry->GetMatrixColumn(i)[j];
         upsampledRegion.SetSize(0, geometry->GetExtent(0)*m_UpsamplingFactor);
         upsampledRegion.SetSize(1, geometry->GetExtent(1)*m_UpsamplingFactor);
         upsampledRegion.SetSize(2, geometry->GetExtent(2)*m_UpsamplingFactor);
     }
     typename OutputImageType::RegionType::SizeType upsampledSize = upsampledRegion.GetSize();
 
     // apply new image parameters
     outImage->SetSpacing( newSpacing );
     outImage->SetOrigin( newOrigin );
     outImage->SetDirection( newDirection );
     outImage->SetLargestPossibleRegion( upsampledRegion );
     outImage->SetBufferedRegion( upsampledRegion );
     outImage->SetRequestedRegion( upsampledRegion );
     outImage->Allocate();
     outImage->FillBuffer(0.0);
 
     int w = upsampledSize[0];
     int h = upsampledSize[1];
     int d = upsampledSize[2];
 
     // set/initialize output
     OutPixelType* outImageBufferPointer = (OutPixelType*)outImage->GetBufferPointer();
 
     // resample fiber bundle
     float minSpacing = 1;
     if(newSpacing[0]<newSpacing[1] && newSpacing[0]<newSpacing[2])
         minSpacing = newSpacing[0];
     else if (newSpacing[1] < newSpacing[2])
         minSpacing = newSpacing[1];
     else
         minSpacing = newSpacing[2];
 
-    MITK_INFO << "TractDensityImageFilter: resampling fibers to ensure sufficient voxel coverage";
-    if (m_DoFiberResampling)
+    for (int f=0; f<fibs.size(); f++)
     {
-        m_FiberBundle = m_FiberBundle->GetDeepCopy();
-        m_FiberBundle->ResampleSpline(minSpacing/10);
-    }
+        typename OutputImageType::Pointer workingImage = OutputImageType::New();
+        workingImage->SetSpacing( newSpacing );
+        workingImage->SetOrigin( newOrigin );
+        workingImage->SetDirection( newDirection );
+        workingImage->SetLargestPossibleRegion( upsampledRegion );
+        workingImage->SetBufferedRegion( upsampledRegion );
+        workingImage->SetRequestedRegion( upsampledRegion );
+        workingImage->Allocate();
+        workingImage->FillBuffer(0.0);
+
+        m_FiberBundle = fibs.at(f);
+        MITK_INFO << "TractDensityImageFilter: resampling fibers to ensure sufficient voxel coverage";
+        if (m_DoFiberResampling)
+        {
+            m_FiberBundle = m_FiberBundle->GetDeepCopy();
+            m_FiberBundle->ResampleSpline(minSpacing/10);
+        }
 
-    MITK_INFO << "TractDensityImageFilter: starting image generation";
+        MITK_INFO << "TractDensityImageFilter: starting image generation";
 
-    vtkSmartPointer<vtkPolyData> fiberPolyData = m_FiberBundle->GetFiberPolyData();
-    vtkSmartPointer<vtkCellArray> vLines = fiberPolyData->GetLines();
-    vLines->InitTraversal();
-    int numFibers = m_FiberBundle->GetNumFibers();
-    boost::progress_display disp(numFibers);
-    for( int i=0; i<numFibers; i++ )
-    {
-        ++disp;
-        vtkIdType   numPoints(0);
-        vtkIdType*  points(NULL);
-        vLines->GetNextCell ( numPoints, points );
-        float weight = m_FiberBundle->GetFiberWeight(i);
-
-        // fill output image
-        for( int j=0; j<numPoints; j++)
+        vtkSmartPointer<vtkPolyData> fiberPolyData = m_FiberBundle->GetFiberPolyData();
+        vtkSmartPointer<vtkCellArray> vLines = fiberPolyData->GetLines();
+        vLines->InitTraversal();
+        int numFibers = m_FiberBundle->GetNumFibers();
+        boost::progress_display disp(numFibers);
+        for( int i=0; i<numFibers; i++ )
         {
-            itk::Point<float, 3> vertex = GetItkPoint(fiberPolyData->GetPoint(points[j]));
-            itk::Index<3> index;
-            itk::ContinuousIndex<float, 3> contIndex;
-            outImage->TransformPhysicalPointToIndex(vertex, index);
-            outImage->TransformPhysicalPointToContinuousIndex(vertex, contIndex);
-
-            if (!m_UseTrilinearInterpolation && outImage->GetLargestPossibleRegion().IsInside(index))
+            ++disp;
+            vtkIdType   numPoints(0);
+            vtkIdType*  points(NULL);
+            vLines->GetNextCell ( numPoints, points );
+            float weight = m_FiberBundle->GetFiberWeight(i);
+
+            // fill output image
+            for( int j=0; j<numPoints; j++)
             {
+                itk::Point<float, 3> vertex = GetItkPoint(fiberPolyData->GetPoint(points[j]));
+                itk::Index<3> index;
+                itk::ContinuousIndex<float, 3> contIndex;
+                workingImage->TransformPhysicalPointToIndex(vertex, index);
+                workingImage->TransformPhysicalPointToContinuousIndex(vertex, contIndex);
+
                 if (m_BinaryOutput)
-                    outImage->SetPixel(index, 1);
+                    workingImage->SetPixel(index, 1);
                 else
-                    outImage->SetPixel(index, outImage->GetPixel(index)+0.01*weight);
-                continue;
-            }
-
-            float frac_x = contIndex[0] - index[0];
-            float frac_y = contIndex[1] - index[1];
-            float frac_z = contIndex[2] - index[2];
-
-            if (frac_x<0)
-            {
-                index[0] -= 1;
-                frac_x += 1;
-            }
-            if (frac_y<0)
-            {
-                index[1] -= 1;
-                frac_y += 1;
-            }
-            if (frac_z<0)
-            {
-                index[2] -= 1;
-                frac_z += 1;
+                    workingImage->SetPixel(index, workingImage->GetPixel(index)+0.01*weight);
             }
+        }
 
-            frac_x = 1-frac_x;
-            frac_y = 1-frac_y;
-            frac_z = 1-frac_z;
-
-            // int coordinates inside image?
-            if (index[0] < 0 || index[0] >= w-1)
-                continue;
-            if (index[1] < 0 || index[1] >= h-1)
-                continue;
-            if (index[2] < 0 || index[2] >= d-1)
-                continue;
+        OutPixelType* wipImageBufferPointer = (OutPixelType*)workingImage->GetBufferPointer();
+        for (int i=0; i<w*h*d; i++)
+            if (wipImageBufferPointer[i] > outImageBufferPointer[i])
+                outImageBufferPointer[i] = wipImageBufferPointer[i];
 
-            if (m_BinaryOutput)
-            {
-                outImageBufferPointer[( index[0]   + w*(index[1]  + h*index[2]  ))] = 1;
-                outImageBufferPointer[( index[0]   + w*(index[1]+1+ h*index[2]  ))] = 1;
-                outImageBufferPointer[( index[0]   + w*(index[1]  + h*index[2]+h))] = 1;
-                outImageBufferPointer[( index[0]   + w*(index[1]+1+ h*index[2]+h))] = 1;
-                outImageBufferPointer[( index[0]+1 + w*(index[1]  + h*index[2]  ))] = 1;
-                outImageBufferPointer[( index[0]+1 + w*(index[1]  + h*index[2]+h))] = 1;
-                outImageBufferPointer[( index[0]+1 + w*(index[1]+1+ h*index[2]  ))] = 1;
-                outImageBufferPointer[( index[0]+1 + w*(index[1]+1+ h*index[2]+h))] = 1;
-            }
-            else
-            {
-                outImageBufferPointer[( index[0]   + w*(index[1]  + h*index[2]  ))] += (  frac_x)*(  frac_y)*(  frac_z);
-                outImageBufferPointer[( index[0]   + w*(index[1]+1+ h*index[2]  ))] += (  frac_x)*(1-frac_y)*(  frac_z);
-                outImageBufferPointer[( index[0]   + w*(index[1]  + h*index[2]+h))] += (  frac_x)*(  frac_y)*(1-frac_z);
-                outImageBufferPointer[( index[0]   + w*(index[1]+1+ h*index[2]+h))] += (  frac_x)*(1-frac_y)*(1-frac_z);
-                outImageBufferPointer[( index[0]+1 + w*(index[1]  + h*index[2]  ))] += (1-frac_x)*(  frac_y)*(  frac_z);
-                outImageBufferPointer[( index[0]+1 + w*(index[1]  + h*index[2]+h))] += (1-frac_x)*(  frac_y)*(1-frac_z);
-                outImageBufferPointer[( index[0]+1 + w*(index[1]+1+ h*index[2]  ))] += (1-frac_x)*(1-frac_y)*(  frac_z);
-                outImageBufferPointer[( index[0]+1 + w*(index[1]+1+ h*index[2]+h))] += (1-frac_x)*(1-frac_y)*(1-frac_z);
-            }
-        }
     }
 
     if (!m_OutputAbsoluteValues && !m_BinaryOutput)
     {
         MITK_INFO << "TractDensityImageFilter: max-normalizing output image";
         OutPixelType max = 0;
         for (int i=0; i<w*h*d; i++)
             if (max < outImageBufferPointer[i])
                 max = outImageBufferPointer[i];
         if (max>0)
             for (int i=0; i<w*h*d; i++)
             {
                 outImageBufferPointer[i] /= max;
             }
     }
     if (m_InvertImage)
     {
         MITK_INFO << "TractDensityImageFilter: inverting image";
         for (int i=0; i<w*h*d; i++)
             outImageBufferPointer[i] = 1-outImageBufferPointer[i];
     }
     MITK_INFO << "TractDensityImageFilter: finished processing";
 }
 }
diff --git a/Modules/DiffusionImaging/FiberTracking/Algorithms/itkTractDensityImageFilter.h b/Modules/DiffusionImaging/FiberTracking/Algorithms/itkTractDensityImageFilter.h
index fc9c23714e..5f49bb6ae7 100644
--- a/Modules/DiffusionImaging/FiberTracking/Algorithms/itkTractDensityImageFilter.h
+++ b/Modules/DiffusionImaging/FiberTracking/Algorithms/itkTractDensityImageFilter.h
@@ -1,87 +1,89 @@
 /*===================================================================
 
 The Medical Imaging Interaction Toolkit (MITK)
 
 Copyright (c) German Cancer Research Center,
 Division of Medical and Biological Informatics.
 All rights reserved.
 
 This software is distributed WITHOUT ANY WARRANTY; without
 even the implied warranty of MERCHANTABILITY or FITNESS FOR
 A PARTICULAR PURPOSE.
 
 See LICENSE.txt or http://www.mitk.org for details.
 
 ===================================================================*/
 #ifndef __itkTractDensityImageFilter_h__
 #define __itkTractDensityImageFilter_h__
 
 #include <itkImageSource.h>
 #include <itkImage.h>
 #include <itkVectorContainer.h>
 #include <itkRGBAPixel.h>
 #include <mitkFiberBundle.h>
 
 namespace itk{
 
 /**
 * \brief Generates tract density images from input fiberbundles (Calamante 2010).   */
 
 template< class OutputImageType >
 class TractDensityImageFilter : public ImageSource< OutputImageType >
 {
 
 public:
   typedef TractDensityImageFilter Self;
   typedef ProcessObject Superclass;
   typedef SmartPointer< Self > Pointer;
   typedef SmartPointer< const Self > ConstPointer;
 
   typedef typename OutputImageType::PixelType OutPixelType;
 
   itkFactorylessNewMacro(Self)
   itkCloneMacro(Self)
   itkTypeMacro( TractDensityImageFilter, ImageSource )
 
   itkSetMacro( UpsamplingFactor, float)                         ///< use higher resolution for ouput image
   itkGetMacro( UpsamplingFactor, float)                         ///< use higher resolution for ouput image
   itkSetMacro( InvertImage, bool)                               ///< voxelvalue = 1-voxelvalue
   itkGetMacro( InvertImage, bool)                               ///< voxelvalue = 1-voxelvalue
   itkSetMacro( BinaryOutput, bool)                              ///< generate binary fiber envelope
   itkGetMacro( BinaryOutput, bool)                              ///< generate binary fiber envelope
   itkSetMacro( OutputAbsoluteValues, bool)                      ///< output absolute values of the number of fibers per voxel
   itkGetMacro( OutputAbsoluteValues, bool)                      ///< output absolute values of the number of fibers per voxel
   itkSetMacro( UseImageGeometry, bool)                          ///< use input image geometry to initialize output image
   itkGetMacro( UseImageGeometry, bool)                          ///< use input image geometry to initialize output image
   itkSetMacro( FiberBundle, mitk::FiberBundle::Pointer)        ///< input fiber bundle
   itkSetMacro( InputImage, typename OutputImageType::Pointer)   ///< use input image geometry to initialize output image
   itkSetMacro( UseTrilinearInterpolation, bool )
   itkSetMacro( DoFiberResampling, bool )
 
   void GenerateData();
 
+  std::vector< mitk::FiberBundle::Pointer > fibs;
+
 protected:
 
   itk::Point<float, 3> GetItkPoint(double point[3]);
 
   TractDensityImageFilter();
   virtual ~TractDensityImageFilter();
 
   typename OutputImageType::Pointer m_InputImage;           ///< use input image geometry to initialize output image
   mitk::FiberBundle::Pointer       m_FiberBundle;          ///< input fiber bundle
   float                             m_UpsamplingFactor;     ///< use higher resolution for ouput image
   bool                              m_InvertImage;          ///< voxelvalue = 1-voxelvalue
   bool                              m_BinaryOutput;         ///< generate binary fiber envelope
   bool                              m_UseImageGeometry;     ///< use input image geometry to initialize output image
   bool                              m_OutputAbsoluteValues; ///< do not normalize image values to 0-1
   bool                              m_UseTrilinearInterpolation;
   bool                              m_DoFiberResampling;
 };
 
 }
 
 #ifndef ITK_MANUAL_INSTANTIATION
 #include "itkTractDensityImageFilter.cpp"
 #endif
 
 #endif // __itkTractDensityImageFilter_h__
diff --git a/Modules/DiffusionImaging/FiberTracking/Algorithms/itkTractsToDWIImageFilter.cpp b/Modules/DiffusionImaging/FiberTracking/Algorithms/itkTractsToDWIImageFilter.cpp
index 86093896aa..c29d1cb8be 100755
--- a/Modules/DiffusionImaging/FiberTracking/Algorithms/itkTractsToDWIImageFilter.cpp
+++ b/Modules/DiffusionImaging/FiberTracking/Algorithms/itkTractsToDWIImageFilter.cpp
@@ -1,1302 +1,1438 @@
 /*===================================================================
 
 The Medical Imaging Interaction Toolkit (MITK)
 
 Copyright (c) German Cancer Research Center,
 Division of Medical and Biological Informatics.
 All rights reserved.
 
 This software is distributed WITHOUT ANY WARRANTY; without
 even the implied warranty of MERCHANTABILITY or FITNESS FOR
 A PARTICULAR PURPOSE.
 
 See LICENSE.txt or http://www.mitk.org for details.
 
 ===================================================================*/
 
 #include "itkTractsToDWIImageFilter.h"
 #include <boost/progress.hpp>
 #include <vtkSmartPointer.h>
 #include <vtkPolyData.h>
 #include <vtkCellArray.h>
 #include <vtkPoints.h>
 #include <vtkPolyLine.h>
 #include <itkImageRegionIteratorWithIndex.h>
 #include <itkResampleImageFilter.h>
 #include <itkNearestNeighborInterpolateImageFunction.h>
 #include <itkBSplineInterpolateImageFunction.h>
 #include <itkCastImageFilter.h>
 #include <itkImageFileWriter.h>
 #include <itkRescaleIntensityImageFilter.h>
 #include <itkWindowedSincInterpolateImageFunction.h>
 #include <itkResampleDwiImageFilter.h>
 #include <itkKspaceImageFilter.h>
 #include <itkDftImageFilter.h>
 #include <itkAddImageFilter.h>
 #include <itkConstantPadImageFilter.h>
 #include <itkCropImageFilter.h>
 #include <mitkAstroStickModel.h>
 #include <vtkTransform.h>
 #include <iostream>
 #include <fstream>
 #include <itkImageDuplicator.h>
 #include <itksys/SystemTools.hxx>
 #include <mitkIOUtil.h>
 #include <itkDiffusionTensor3DReconstructionImageFilter.h>
 #include <itkDiffusionTensor3D.h>
 #include <itkTractDensityImageFilter.h>
 #include <boost/lexical_cast.hpp>
 #include <itkTractsToVectorImageFilter.h>
 
 namespace itk
 {
 
 template< class PixelType >
 TractsToDWIImageFilter< PixelType >::TractsToDWIImageFilter()
     : m_FiberBundle(NULL)
     , m_StatusText("")
     , m_UseConstantRandSeed(false)
     , m_RandGen(itk::Statistics::MersenneTwisterRandomVariateGenerator::New())
 {
     m_RandGen->SetSeed();
 }
 
 template< class PixelType >
 TractsToDWIImageFilter< PixelType >::~TractsToDWIImageFilter()
 {
 
 }
 
 template< class PixelType >
 TractsToDWIImageFilter< PixelType >::DoubleDwiType::Pointer TractsToDWIImageFilter< PixelType >::DoKspaceStuff( std::vector< DoubleDwiType::Pointer >& images )
 {
     int numFiberCompartments = m_Parameters.m_FiberModelList.size();
     // create slice object
     ImageRegion<2> sliceRegion;
     sliceRegion.SetSize(0, m_UpsampledImageRegion.GetSize()[0]);
     sliceRegion.SetSize(1, m_UpsampledImageRegion.GetSize()[1]);
     Vector< double, 2 > sliceSpacing;
     sliceSpacing[0] = m_UpsampledSpacing[0];
     sliceSpacing[1] = m_UpsampledSpacing[1];
 
     // frequency map slice
     SliceType::Pointer fMapSlice = NULL;
     if (m_Parameters.m_SignalGen.m_FrequencyMap.IsNotNull())
     {
         fMapSlice = SliceType::New();
         ImageRegion<2> region;
         region.SetSize(0, m_UpsampledImageRegion.GetSize()[0]);
         region.SetSize(1, m_UpsampledImageRegion.GetSize()[1]);
         fMapSlice->SetLargestPossibleRegion( region );
         fMapSlice->SetBufferedRegion( region );
         fMapSlice->SetRequestedRegion( region );
         fMapSlice->Allocate();
         fMapSlice->FillBuffer(0.0);
     }
 
     DoubleDwiType::Pointer newImage = DoubleDwiType::New();
     newImage->SetSpacing( m_Parameters.m_SignalGen.m_ImageSpacing );
     newImage->SetOrigin( m_Parameters.m_SignalGen.m_ImageOrigin );
     newImage->SetDirection( m_Parameters.m_SignalGen.m_ImageDirection );
     newImage->SetLargestPossibleRegion( m_Parameters.m_SignalGen.m_ImageRegion );
     newImage->SetBufferedRegion( m_Parameters.m_SignalGen.m_ImageRegion );
     newImage->SetRequestedRegion( m_Parameters.m_SignalGen.m_ImageRegion );
     newImage->SetVectorLength( images.at(0)->GetVectorLength() );
     newImage->Allocate();
 
     std::vector< unsigned int > spikeVolume;
     for (unsigned int i=0; i<m_Parameters.m_SignalGen.m_Spikes; i++)
-        spikeVolume.push_back(m_RandGen->GetIntegerVariate()%images.at(0)->GetVectorLength());
+        spikeVolume.push_back(m_RandGen->GetIntegerVariate()%(images.at(0)->GetVectorLength()-1)+1);
     std::sort (spikeVolume.begin(), spikeVolume.end());
     std::reverse (spikeVolume.begin(), spikeVolume.end());
 
     m_StatusText += "0%   10   20   30   40   50   60   70   80   90   100%\n";
     m_StatusText += "|----|----|----|----|----|----|----|----|----|----|\n*";
     unsigned long lastTick = 0;
 
     boost::progress_display disp(2*images.at(0)->GetVectorLength()*images.at(0)->GetLargestPossibleRegion().GetSize(2));
     for (unsigned int g=0; g<images.at(0)->GetVectorLength(); g++)
     {
         std::vector< unsigned int > spikeSlice;
         while (!spikeVolume.empty() && spikeVolume.back()==g)
         {
             spikeSlice.push_back(m_RandGen->GetIntegerVariate()%images.at(0)->GetLargestPossibleRegion().GetSize(2));
             spikeVolume.pop_back();
         }
         std::sort (spikeSlice.begin(), spikeSlice.end());
         std::reverse (spikeSlice.begin(), spikeSlice.end());
 
         for (unsigned int z=0; z<images.at(0)->GetLargestPossibleRegion().GetSize(2); z++)
         {
             std::vector< SliceType::Pointer > compartmentSlices;
             std::vector< double > t2Vector;
 
             for (unsigned int i=0; i<images.size(); i++)
             {
                 DiffusionSignalModel<double>* signalModel;
                 if (i<numFiberCompartments)
                     signalModel = m_Parameters.m_FiberModelList.at(i);
                 else
                     signalModel = m_Parameters.m_NonFiberModelList.at(i-numFiberCompartments);
 
                 SliceType::Pointer slice = SliceType::New();
                 slice->SetLargestPossibleRegion( sliceRegion );
                 slice->SetBufferedRegion( sliceRegion );
                 slice->SetRequestedRegion( sliceRegion );
                 slice->SetSpacing(sliceSpacing);
                 slice->Allocate();
                 slice->FillBuffer(0.0);
 
                 // extract slice from channel g
                 for (unsigned int y=0; y<images.at(0)->GetLargestPossibleRegion().GetSize(1); y++)
                     for (unsigned int x=0; x<images.at(0)->GetLargestPossibleRegion().GetSize(0); x++)
                     {
                         SliceType::IndexType index2D; index2D[0]=x; index2D[1]=y;
                         DoubleDwiType::IndexType index3D; index3D[0]=x; index3D[1]=y; index3D[2]=z;
 
                         slice->SetPixel(index2D, images.at(i)->GetPixel(index3D)[g]);
 
                         if (fMapSlice.IsNotNull() && i==0)
                             fMapSlice->SetPixel(index2D, m_Parameters.m_SignalGen.m_FrequencyMap->GetPixel(index3D));
                     }
 
                 compartmentSlices.push_back(slice);
                 t2Vector.push_back(signalModel->GetT2());
             }
 
             if (this->GetAbortGenerateData())
                 return NULL;
 
             // create k-sapce (inverse fourier transform slices)
             itk::Size<2> outSize; outSize.SetElement(0, m_Parameters.m_SignalGen.m_ImageRegion.GetSize(0)); outSize.SetElement(1, m_Parameters.m_SignalGen.m_ImageRegion.GetSize(1));
             itk::KspaceImageFilter< SliceType::PixelType >::Pointer idft = itk::KspaceImageFilter< SliceType::PixelType >::New();
             idft->SetCompartmentImages(compartmentSlices);
             idft->SetT2(t2Vector);
             idft->SetUseConstantRandSeed(m_UseConstantRandSeed);
             idft->SetParameters(m_Parameters);
             idft->SetZ((double)z-(double)images.at(0)->GetLargestPossibleRegion().GetSize(2)/2.0);
             idft->SetDiffusionGradientDirection(m_Parameters.m_SignalGen.GetGradientDirection(g));
             idft->SetFrequencyMapSlice(fMapSlice);
             idft->SetOutSize(outSize);
             int numSpikes = 0;
             while (!spikeSlice.empty() && spikeSlice.back()==z)
             {
                 numSpikes++;
                 spikeSlice.pop_back();
             }
             idft->SetSpikesPerSlice(numSpikes);
             idft->Update();
 
             ComplexSliceType::Pointer fSlice;
             fSlice = idft->GetOutput();
 
             ++disp;
             unsigned long newTick = 50*disp.count()/disp.expected_count();
             for (unsigned  long tick = 0; tick<(newTick-lastTick); tick++)
                 m_StatusText += "*";
             lastTick = newTick;
 
             // fourier transform slice
             SliceType::Pointer newSlice;
             itk::DftImageFilter< SliceType::PixelType >::Pointer dft = itk::DftImageFilter< SliceType::PixelType >::New();
             dft->SetInput(fSlice);
             dft->Update();
             newSlice = dft->GetOutput();
 
             // put slice back into channel g
             for (unsigned int y=0; y<fSlice->GetLargestPossibleRegion().GetSize(1); y++)
                 for (unsigned int x=0; x<fSlice->GetLargestPossibleRegion().GetSize(0); x++)
                 {
                     DoubleDwiType::IndexType index3D; index3D[0]=x; index3D[1]=y; index3D[2]=z;
                     SliceType::IndexType index2D; index2D[0]=x; index2D[1]=y;
 
                     DoubleDwiType::PixelType pix3D = newImage->GetPixel(index3D);
                     pix3D[g] = newSlice->GetPixel(index2D);
                     newImage->SetPixel(index3D, pix3D);
                 }
             ++disp;
             newTick = 50*disp.count()/disp.expected_count();
             for (unsigned long tick = 0; tick<(newTick-lastTick); tick++)
                 m_StatusText += "*";
             lastTick = newTick;
         }
     }
     m_StatusText += "\n\n";
     return newImage;
 }
 
 template< class PixelType >
 void TractsToDWIImageFilter< PixelType >::GenerateData()
 {
     m_TimeProbe.Start();
     m_StatusText = "Starting simulation\n";
 
     // check input data
     if (m_FiberBundle.IsNull())
         itkExceptionMacro("Input fiber bundle is NULL!");
 
     if (m_Parameters.m_FiberModelList.empty())
         itkExceptionMacro("No diffusion model for fiber compartments defined!");
 
     if (m_Parameters.m_NonFiberModelList.empty())
         itkExceptionMacro("No diffusion model for non-fiber compartments defined!");
 
     int baselineIndex = m_Parameters.m_SignalGen.GetFirstBaselineIndex();
     if (baselineIndex<0)
         itkExceptionMacro("No baseline index found!");
 
     if (!m_Parameters.m_SignalGen.m_SimulateKspaceAcquisition)
         m_Parameters.m_SignalGen.m_DoAddGibbsRinging = false;
 
     if (m_UseConstantRandSeed)  // always generate the same random numbers?
         m_RandGen->SetSeed(0);
     else
         m_RandGen->SetSeed();
 
     // initialize output dwi image
     ImageRegion<3> croppedRegion = m_Parameters.m_SignalGen.m_ImageRegion; croppedRegion.SetSize(1, croppedRegion.GetSize(1)*m_Parameters.m_SignalGen.m_CroppingFactor);
     itk::Point<double,3> shiftedOrigin = m_Parameters.m_SignalGen.m_ImageOrigin; shiftedOrigin[1] += (m_Parameters.m_SignalGen.m_ImageRegion.GetSize(1)-croppedRegion.GetSize(1))*m_Parameters.m_SignalGen.m_ImageSpacing[1]/2;
     typename OutputImageType::Pointer outImage = OutputImageType::New();
     outImage->SetSpacing( m_Parameters.m_SignalGen.m_ImageSpacing );
     outImage->SetOrigin( shiftedOrigin );
     outImage->SetDirection( m_Parameters.m_SignalGen.m_ImageDirection );
     outImage->SetLargestPossibleRegion( croppedRegion );
     outImage->SetBufferedRegion( croppedRegion );
     outImage->SetRequestedRegion( croppedRegion );
     outImage->SetVectorLength( m_Parameters.m_SignalGen.GetNumVolumes() );
     outImage->Allocate();
     typename OutputImageType::PixelType temp;
     temp.SetSize(m_Parameters.m_SignalGen.GetNumVolumes());
     temp.Fill(0.0);
     outImage->FillBuffer(temp);
 
     // ADJUST GEOMETRY FOR FURTHER PROCESSING
     // is input slize size a power of two?
     unsigned int x=m_Parameters.m_SignalGen.m_ImageRegion.GetSize(0); unsigned int y=m_Parameters.m_SignalGen.m_ImageRegion.GetSize(1);
     ItkDoubleImgType::SizeType pad; pad[0]=x%2; pad[1]=y%2; pad[2]=0;
     m_Parameters.m_SignalGen.m_ImageRegion.SetSize(0, x+pad[0]);
     m_Parameters.m_SignalGen.m_ImageRegion.SetSize(1, y+pad[1]);
     if (m_Parameters.m_SignalGen.m_FrequencyMap.IsNotNull() && (pad[0]>0 || pad[1]>0))
     {
         itk::ConstantPadImageFilter<ItkDoubleImgType, ItkDoubleImgType>::Pointer zeroPadder = itk::ConstantPadImageFilter<ItkDoubleImgType, ItkDoubleImgType>::New();
         zeroPadder->SetInput(m_Parameters.m_SignalGen.m_FrequencyMap);
         zeroPadder->SetConstant(0);
         zeroPadder->SetPadUpperBound(pad);
         zeroPadder->Update();
         m_Parameters.m_SignalGen.m_FrequencyMap = zeroPadder->GetOutput();
     }
     if (m_Parameters.m_SignalGen.m_MaskImage.IsNotNull() && (pad[0]>0 || pad[1]>0))
     {
         itk::ConstantPadImageFilter<ItkUcharImgType, ItkUcharImgType>::Pointer zeroPadder = itk::ConstantPadImageFilter<ItkUcharImgType, ItkUcharImgType>::New();
         zeroPadder->SetInput(m_Parameters.m_SignalGen.m_MaskImage);
         zeroPadder->SetConstant(0);
         zeroPadder->SetPadUpperBound(pad);
         zeroPadder->Update();
         m_Parameters.m_SignalGen.m_MaskImage = zeroPadder->GetOutput();
     }
 
     // Apply in-plane upsampling for Gibbs ringing artifact
     double upsampling = 1;
     if (m_Parameters.m_SignalGen.m_DoAddGibbsRinging)
         upsampling = 2;
     m_UpsampledSpacing = m_Parameters.m_SignalGen.m_ImageSpacing;
     m_UpsampledSpacing[0] /= upsampling;
     m_UpsampledSpacing[1] /= upsampling;
     m_UpsampledImageRegion = m_Parameters.m_SignalGen.m_ImageRegion;
     m_UpsampledImageRegion.SetSize(0, m_Parameters.m_SignalGen.m_ImageRegion.GetSize()[0]*upsampling);
     m_UpsampledImageRegion.SetSize(1, m_Parameters.m_SignalGen.m_ImageRegion.GetSize()[1]*upsampling);
     m_UpsampledOrigin = m_Parameters.m_SignalGen.m_ImageOrigin;
     m_UpsampledOrigin[0] -= m_Parameters.m_SignalGen.m_ImageSpacing[0]/2; m_UpsampledOrigin[0] += m_UpsampledSpacing[0]/2;
     m_UpsampledOrigin[1] -= m_Parameters.m_SignalGen.m_ImageSpacing[1]/2; m_UpsampledOrigin[1] += m_UpsampledSpacing[1]/2;
     m_UpsampledOrigin[2] -= m_Parameters.m_SignalGen.m_ImageSpacing[2]/2; m_UpsampledOrigin[2] += m_UpsampledSpacing[2]/2;
 
     // generate double images to store the individual compartment signals
     m_CompartmentImages.clear();
     int numFiberCompartments = m_Parameters.m_FiberModelList.size();
     int numNonFiberCompartments = m_Parameters.m_NonFiberModelList.size();
 
     for (int i=0; i<numFiberCompartments+numNonFiberCompartments; i++)
     {
         DoubleDwiType::Pointer doubleDwi = DoubleDwiType::New();
         doubleDwi->SetSpacing( m_UpsampledSpacing );
         doubleDwi->SetOrigin( m_UpsampledOrigin );
         doubleDwi->SetDirection( m_Parameters.m_SignalGen.m_ImageDirection );
         doubleDwi->SetLargestPossibleRegion( m_UpsampledImageRegion );
         doubleDwi->SetBufferedRegion( m_UpsampledImageRegion );
         doubleDwi->SetRequestedRegion( m_UpsampledImageRegion );
         doubleDwi->SetVectorLength( m_Parameters.m_SignalGen.GetNumVolumes() );
         doubleDwi->Allocate();
         DoubleDwiType::PixelType pix;
         pix.SetSize(m_Parameters.m_SignalGen.GetNumVolumes());
         pix.Fill(0.0);
         doubleDwi->FillBuffer(pix);
         m_CompartmentImages.push_back(doubleDwi);
     }
 
     // initialize output volume fraction images
     m_VolumeFractions.clear();
     for (int i=0; i<numFiberCompartments+numNonFiberCompartments; i++)
     {
         ItkDoubleImgType::Pointer doubleImg = ItkDoubleImgType::New();
         doubleImg->SetSpacing( m_UpsampledSpacing );
         doubleImg->SetOrigin( m_UpsampledOrigin );
         doubleImg->SetDirection( m_Parameters.m_SignalGen.m_ImageDirection );
         doubleImg->SetLargestPossibleRegion( m_UpsampledImageRegion );
         doubleImg->SetBufferedRegion( m_UpsampledImageRegion );
         doubleImg->SetRequestedRegion( m_UpsampledImageRegion );
         doubleImg->Allocate();
         doubleImg->FillBuffer(0);
         m_VolumeFractions.push_back(doubleImg);
     }
 
     // get volume fraction images
     ItkDoubleImgType::Pointer sumImage = ItkDoubleImgType::New();
     bool foundVolumeFractionImage = false;
 
     for (int i=0; i<numNonFiberCompartments; i++)  // look if a volume fraction image is set
     {
         if (m_Parameters.m_NonFiberModelList[i]->GetVolumeFractionImage().IsNotNull())
         {
             foundVolumeFractionImage = true;
 
             itk::ConstantPadImageFilter<ItkDoubleImgType, ItkDoubleImgType>::Pointer zeroPadder = itk::ConstantPadImageFilter<ItkDoubleImgType, ItkDoubleImgType>::New();
             zeroPadder->SetInput(m_Parameters.m_NonFiberModelList[i]->GetVolumeFractionImage());
             zeroPadder->SetConstant(0);
             zeroPadder->SetPadUpperBound(pad);
             zeroPadder->Update();
             m_Parameters.m_NonFiberModelList[i]->SetVolumeFractionImage(zeroPadder->GetOutput());
 
             sumImage->SetSpacing( m_Parameters.m_NonFiberModelList[i]->GetVolumeFractionImage()->GetSpacing() );
             sumImage->SetOrigin( m_Parameters.m_NonFiberModelList[i]->GetVolumeFractionImage()->GetOrigin() );
             sumImage->SetDirection( m_Parameters.m_NonFiberModelList[i]->GetVolumeFractionImage()->GetDirection() );
             sumImage->SetLargestPossibleRegion( m_Parameters.m_NonFiberModelList[i]->GetVolumeFractionImage()->GetLargestPossibleRegion() );
             sumImage->SetBufferedRegion( m_Parameters.m_NonFiberModelList[i]->GetVolumeFractionImage()->GetLargestPossibleRegion() );
             sumImage->SetRequestedRegion( m_Parameters.m_NonFiberModelList[i]->GetVolumeFractionImage()->GetLargestPossibleRegion() );
             sumImage->Allocate();
             sumImage->FillBuffer(0);
             break;
         }
     }
     if (!foundVolumeFractionImage)
     {
         sumImage->SetSpacing( m_UpsampledSpacing );
         sumImage->SetOrigin( m_UpsampledOrigin );
         sumImage->SetDirection( m_Parameters.m_SignalGen.m_ImageDirection );
         sumImage->SetLargestPossibleRegion( m_UpsampledImageRegion );
         sumImage->SetBufferedRegion( m_UpsampledImageRegion );
         sumImage->SetRequestedRegion( m_UpsampledImageRegion );
         sumImage->Allocate();
         sumImage->FillBuffer(0.0);
     }
     for (int i=0; i<numNonFiberCompartments; i++)
     {
         if (m_Parameters.m_NonFiberModelList[i]->GetVolumeFractionImage().IsNull())
         {
+            MITK_INFO << "ERROR";
             ItkDoubleImgType::Pointer doubleImg = ItkDoubleImgType::New();
             doubleImg->SetSpacing( sumImage->GetSpacing() );
             doubleImg->SetOrigin( sumImage->GetOrigin() );
             doubleImg->SetDirection( sumImage->GetDirection() );
             doubleImg->SetLargestPossibleRegion( sumImage->GetLargestPossibleRegion() );
             doubleImg->SetBufferedRegion( sumImage->GetLargestPossibleRegion() );
             doubleImg->SetRequestedRegion( sumImage->GetLargestPossibleRegion() );
             doubleImg->Allocate();
             doubleImg->FillBuffer(1.0/numNonFiberCompartments);
             m_Parameters.m_NonFiberModelList[i]->SetVolumeFractionImage(doubleImg);
         }
         ImageRegionIterator<ItkDoubleImgType> it(m_Parameters.m_NonFiberModelList[i]->GetVolumeFractionImage(), m_Parameters.m_NonFiberModelList[i]->GetVolumeFractionImage()->GetLargestPossibleRegion());
         while(!it.IsAtEnd())
         {
             sumImage->SetPixel(it.GetIndex(), sumImage->GetPixel(it.GetIndex())+it.Get());
             ++it;
         }
     }
     for (int i=0; i<numNonFiberCompartments; i++)
     {
         ImageRegionIterator<ItkDoubleImgType> it(m_Parameters.m_NonFiberModelList[i]->GetVolumeFractionImage(), m_Parameters.m_NonFiberModelList[i]->GetVolumeFractionImage()->GetLargestPossibleRegion());
         while(!it.IsAtEnd())
         {
             if (sumImage->GetPixel(it.GetIndex())>0)
                 it.Set(it.Get()/sumImage->GetPixel(it.GetIndex()));
             ++it;
         }
     }
 
     // resample mask image and frequency map to fit upsampled geometry
     if (m_Parameters.m_SignalGen.m_DoAddGibbsRinging)
     {
         if (m_Parameters.m_SignalGen.m_MaskImage.IsNotNull())
         {
             // rescale mask image (otherwise there are problems with the resampling)
             itk::RescaleIntensityImageFilter<ItkUcharImgType,ItkUcharImgType>::Pointer rescaler = itk::RescaleIntensityImageFilter<ItkUcharImgType,ItkUcharImgType>::New();
             rescaler->SetInput(0,m_Parameters.m_SignalGen.m_MaskImage);
             rescaler->SetOutputMaximum(100);
             rescaler->SetOutputMinimum(0);
             rescaler->Update();
 
             // resample mask image
             itk::ResampleImageFilter<ItkUcharImgType, ItkUcharImgType>::Pointer resampler = itk::ResampleImageFilter<ItkUcharImgType, ItkUcharImgType>::New();
             resampler->SetInput(rescaler->GetOutput());
             resampler->SetOutputParametersFromImage(m_Parameters.m_SignalGen.m_MaskImage);
             resampler->SetSize(m_UpsampledImageRegion.GetSize());
             resampler->SetOutputSpacing(m_UpsampledSpacing);
             resampler->SetOutputOrigin(m_UpsampledOrigin);
             itk::NearestNeighborInterpolateImageFunction<ItkUcharImgType, double>::Pointer nn_interpolator
                     = itk::NearestNeighborInterpolateImageFunction<ItkUcharImgType, double>::New();
             resampler->SetInterpolator(nn_interpolator);
             resampler->Update();
             m_Parameters.m_SignalGen.m_MaskImage = resampler->GetOutput();
 
             itk::ImageFileWriter<ItkUcharImgType>::Pointer w = itk::ImageFileWriter<ItkUcharImgType>::New();
             w->SetFileName("/local/mask_ups.nrrd");
             w->SetInput(m_Parameters.m_SignalGen.m_MaskImage);
             w->Update();
         }
         // resample frequency map
         if (m_Parameters.m_SignalGen.m_FrequencyMap.IsNotNull())
         {
             itk::ResampleImageFilter<ItkDoubleImgType, ItkDoubleImgType>::Pointer resampler = itk::ResampleImageFilter<ItkDoubleImgType, ItkDoubleImgType>::New();
             resampler->SetInput(m_Parameters.m_SignalGen.m_FrequencyMap);
             resampler->SetOutputParametersFromImage(m_Parameters.m_SignalGen.m_FrequencyMap);
             resampler->SetSize(m_UpsampledImageRegion.GetSize());
             resampler->SetOutputSpacing(m_UpsampledSpacing);
             resampler->SetOutputOrigin(m_UpsampledOrigin);
             itk::NearestNeighborInterpolateImageFunction<ItkDoubleImgType, double>::Pointer nn_interpolator
                     = itk::NearestNeighborInterpolateImageFunction<ItkDoubleImgType, double>::New();
             resampler->SetInterpolator(nn_interpolator);
             resampler->Update();
             m_Parameters.m_SignalGen.m_FrequencyMap = resampler->GetOutput();
         }
     }
 
     // no input tissue mask is set -> create default
     m_MaskImageSet = true;
     if (m_Parameters.m_SignalGen.m_MaskImage.IsNull())
     {
         m_StatusText += "No tissue mask set\n";
         MITK_INFO << "No tissue mask set";
         m_Parameters.m_SignalGen.m_MaskImage = ItkUcharImgType::New();
         m_Parameters.m_SignalGen.m_MaskImage->SetSpacing( m_UpsampledSpacing );
         m_Parameters.m_SignalGen.m_MaskImage->SetOrigin( m_UpsampledOrigin );
         m_Parameters.m_SignalGen.m_MaskImage->SetDirection( m_Parameters.m_SignalGen.m_ImageDirection );
         m_Parameters.m_SignalGen.m_MaskImage->SetLargestPossibleRegion( m_UpsampledImageRegion );
         m_Parameters.m_SignalGen.m_MaskImage->SetBufferedRegion( m_UpsampledImageRegion );
         m_Parameters.m_SignalGen.m_MaskImage->SetRequestedRegion( m_UpsampledImageRegion );
         m_Parameters.m_SignalGen.m_MaskImage->Allocate();
         m_Parameters.m_SignalGen.m_MaskImage->FillBuffer(1);
         m_MaskImageSet = false;
     }
     else
     {
         m_StatusText += "Using tissue mask\n";
         MITK_INFO << "Using tissue mask";
     }
 
     m_Parameters.m_SignalGen.m_ImageRegion = croppedRegion;
     x=m_Parameters.m_SignalGen.m_ImageRegion.GetSize(0); y=m_Parameters.m_SignalGen.m_ImageRegion.GetSize(1);
     if ( x%2 == 1 )
         m_Parameters.m_SignalGen.m_ImageRegion.SetSize(0, x+1);
     if ( y%2 == 1 )
         m_Parameters.m_SignalGen.m_ImageRegion.SetSize(1, y+1);
 
     // resample fiber bundle for sufficient voxel coverage
     m_StatusText += "\n"+this->GetTime()+" > Resampling fibers ...\n";
     double segmentVolume = 0.0001;
     float minSpacing = 1;
     if(m_UpsampledSpacing[0]<m_UpsampledSpacing[1] && m_UpsampledSpacing[0]<m_UpsampledSpacing[2])
         minSpacing = m_UpsampledSpacing[0];
     else if (m_UpsampledSpacing[1] < m_UpsampledSpacing[2])
         minSpacing = m_UpsampledSpacing[1];
     else
         minSpacing = m_UpsampledSpacing[2];
     m_FiberBundleWorkingCopy = m_FiberBundle->GetDeepCopy();
     double volumeAccuracy = 10;
     m_FiberBundleWorkingCopy->ResampleSpline(minSpacing/volumeAccuracy);
     double mmRadius = m_Parameters.m_SignalGen.m_AxonRadius/1000;
     if (mmRadius>0)
         segmentVolume = M_PI*mmRadius*mmRadius*minSpacing/volumeAccuracy;
 
     double maxVolume = 0;
     m_VoxelVolume = m_UpsampledSpacing[0]*m_UpsampledSpacing[1]*m_UpsampledSpacing[2];
 
     if (m_Parameters.m_SignalGen.m_DoAddMotion)
     {
         std::string fileName = "fiberfox_motion_0.log";
         std::string filePath = mitk::IOUtil::GetTempPath();
         if (m_Parameters.m_Misc.m_OutputPath.size()>0)
             filePath = m_Parameters.m_Misc.m_OutputPath;
 
         int c = 1;
 
         while (itksys::SystemTools::FileExists((filePath+fileName).c_str()))
         {
             fileName = "fiberfox_motion_";
             fileName += boost::lexical_cast<std::string>(c);
             fileName += ".log";
             c++;
         }
 
         m_Logfile.open((filePath+fileName).c_str());
         m_Logfile << "0 rotation: 0,0,0; translation: 0,0,0\n";
 
         if (m_Parameters.m_SignalGen.m_DoRandomizeMotion)
         {
             m_StatusText += "Adding random motion artifacts:\n";
             m_StatusText += "Maximum rotation: +/-" + boost::lexical_cast<std::string>(m_Parameters.m_SignalGen.m_Rotation) + "°\n";
             m_StatusText += "Maximum translation: +/-" + boost::lexical_cast<std::string>(m_Parameters.m_SignalGen.m_Translation) + "mm\n";
         }
         else
         {
             m_StatusText += "Adding linear motion artifacts:\n";
             m_StatusText += "Maximum rotation: " + boost::lexical_cast<std::string>(m_Parameters.m_SignalGen.m_Rotation) + "°\n";
             m_StatusText += "Maximum translation: " + boost::lexical_cast<std::string>(m_Parameters.m_SignalGen.m_Translation) + "mm\n";
         }
         m_StatusText += "Motion logfile: " + (filePath+fileName) + "\n";
         MITK_INFO << "Adding motion artifacts";
         MITK_INFO << "Maximum rotation: " << m_Parameters.m_SignalGen.m_Rotation;
         MITK_INFO << "Maxmimum translation: " << m_Parameters.m_SignalGen.m_Translation;
     }
     maxVolume = 0;
 
     m_StatusText += "\n"+this->GetTime()+" > Generating " + boost::lexical_cast<std::string>(numFiberCompartments+numNonFiberCompartments) + "-compartment diffusion-weighted signal.\n";
     MITK_INFO << "Generating " << numFiberCompartments+numNonFiberCompartments << "-compartment diffusion-weighted signal.";
     int numFibers = m_FiberBundle->GetNumFibers();
     boost::progress_display disp(numFibers*m_Parameters.m_SignalGen.GetNumVolumes());
 
 
     // get transform for motion artifacts
     m_FiberBundleTransformed = m_FiberBundleWorkingCopy;
     m_Rotation = m_Parameters.m_SignalGen.m_Rotation/m_Parameters.m_SignalGen.GetNumVolumes();
     m_Translation = m_Parameters.m_SignalGen.m_Translation/m_Parameters.m_SignalGen.GetNumVolumes();
 
     // creat image to hold transformed mask (motion artifact)
     m_MaskImage = ItkUcharImgType::New();
     itk::ImageDuplicator<ItkUcharImgType>::Pointer duplicator = itk::ImageDuplicator<ItkUcharImgType>::New();
     duplicator->SetInputImage(m_Parameters.m_SignalGen.m_MaskImage);
     duplicator->Update();
     m_MaskImage = duplicator->GetOutput();
 
     // second upsampling needed for motion artifacts
     ImageRegion<3>      upsampledImageRegion = m_UpsampledImageRegion;
     DoubleVectorType    upsampledSpacing = m_UpsampledSpacing;
     upsampledSpacing[0] /= 4;
     upsampledSpacing[1] /= 4;
     upsampledSpacing[2] /= 4;
     upsampledImageRegion.SetSize(0, m_UpsampledImageRegion.GetSize()[0]*4);
     upsampledImageRegion.SetSize(1, m_UpsampledImageRegion.GetSize()[1]*4);
     upsampledImageRegion.SetSize(2, m_UpsampledImageRegion.GetSize()[2]*4);
     itk::Point<double,3> upsampledOrigin = m_UpsampledOrigin;
     upsampledOrigin[0] -= m_UpsampledSpacing[0]/2; upsampledOrigin[0] += upsampledSpacing[0]/2;
     upsampledOrigin[1] -= m_UpsampledSpacing[1]/2; upsampledOrigin[1] += upsampledSpacing[1]/2;
     upsampledOrigin[2] -= m_UpsampledSpacing[2]/2; upsampledOrigin[2] += upsampledSpacing[2]/2;
     m_UpsampledMaskImage = ItkUcharImgType::New();
     itk::ResampleImageFilter<ItkUcharImgType, ItkUcharImgType>::Pointer upsampler = itk::ResampleImageFilter<ItkUcharImgType, ItkUcharImgType>::New();
     upsampler->SetInput(m_Parameters.m_SignalGen.m_MaskImage);
     upsampler->SetOutputParametersFromImage(m_Parameters.m_SignalGen.m_MaskImage);
     upsampler->SetSize(upsampledImageRegion.GetSize());
     upsampler->SetOutputSpacing(upsampledSpacing);
     upsampler->SetOutputOrigin(upsampledOrigin);
     itk::NearestNeighborInterpolateImageFunction<ItkUcharImgType, double>::Pointer nn_interpolator
             = itk::NearestNeighborInterpolateImageFunction<ItkUcharImgType, double>::New();
     upsampler->SetInterpolator(nn_interpolator);
     upsampler->Update();
     m_UpsampledMaskImage = upsampler->GetOutput();
 
+    if (m_HelperTdi.IsNotNull())
+    {
+        itk::ResampleImageFilter<ItkFloatImgType, ItkFloatImgType>::Pointer upsampler = itk::ResampleImageFilter<ItkFloatImgType, ItkFloatImgType>::New();
+        upsampler->SetInput(m_HelperTdi);
+        upsampler->SetOutputParametersFromImage(m_HelperTdi);
+        upsampler->SetSize(upsampledImageRegion.GetSize());
+        upsampler->SetOutputSpacing(upsampledSpacing);
+        upsampler->SetOutputOrigin(upsampledOrigin);
+        itk::LinearInterpolateImageFunction<ItkFloatImgType, double>::Pointer nn_interpolator
+                = itk::LinearInterpolateImageFunction<ItkFloatImgType, double>::New();
+        upsampler->SetInterpolator(nn_interpolator);
+        upsampler->Update();
+        m_HelperTdiUpsampled = upsampler->GetOutput();
+
+        m_HelperTdiTransformed = ItkFloatImgType::New();
+        itk::ImageDuplicator<ItkFloatImgType>::Pointer duplicator = itk::ImageDuplicator<ItkFloatImgType>::New();
+        duplicator->SetInputImage(m_HelperTdi);
+        duplicator->Update();
+        m_HelperTdiTransformed = duplicator->GetOutput();
+
+        m_HelperTdiCounter = ItkUcharImgType::New();
+        itk::ImageDuplicator<ItkUcharImgType>::Pointer duplicator2 = itk::ImageDuplicator<ItkUcharImgType>::New();
+        duplicator2->SetInputImage(m_MaskImage);
+        duplicator2->Update();
+        m_HelperTdiCounter = duplicator2->GetOutput();
+    }
+
     unsigned long lastTick = 0;
     int signalModelSeed = m_RandGen->GetIntegerVariate();
     switch (m_Parameters.m_SignalGen.m_DiffusionDirectionMode)
     {
     case(SignalGenerationParameters::FIBER_TANGENT_DIRECTIONS):   // use fiber tangent directions to determine diffusion direction
     {
         m_StatusText += "0%   10   20   30   40   50   60   70   80   90   100%\n";
         m_StatusText += "|----|----|----|----|----|----|----|----|----|----|\n*";
 
         for (unsigned int g=0; g<m_Parameters.m_SignalGen.GetNumVolumes(); g++)
         {
             // Set signal model random generator seeds to get same configuration in each voxel
             for (int i=0; i<m_Parameters.m_FiberModelList.size(); i++)
                 m_Parameters.m_FiberModelList.at(i)->SetSeed(signalModelSeed);
             for (int i=0; i<m_Parameters.m_NonFiberModelList.size(); i++)
                 m_Parameters.m_NonFiberModelList.at(i)->SetSeed(signalModelSeed);
 
             ItkDoubleImgType::Pointer intraAxonalVolumeImage = ItkDoubleImgType::New();
             intraAxonalVolumeImage->SetSpacing( m_UpsampledSpacing );
             intraAxonalVolumeImage->SetOrigin( m_UpsampledOrigin );
             intraAxonalVolumeImage->SetDirection( m_Parameters.m_SignalGen.m_ImageDirection );
             intraAxonalVolumeImage->SetLargestPossibleRegion( m_UpsampledImageRegion );
             intraAxonalVolumeImage->SetBufferedRegion( m_UpsampledImageRegion );
             intraAxonalVolumeImage->SetRequestedRegion( m_UpsampledImageRegion );
             intraAxonalVolumeImage->Allocate();
             intraAxonalVolumeImage->FillBuffer(0);
 
             vtkPolyData* fiberPolyData = m_FiberBundleTransformed->GetFiberPolyData();
 
+            // GET TDI
+            ItkDoubleImgType::Pointer TDI = ItkDoubleImgType::New();
+            TDI->SetSpacing( m_UpsampledSpacing );
+            TDI->SetOrigin( m_UpsampledOrigin );
+            TDI->SetDirection( m_Parameters.m_SignalGen.m_ImageDirection );
+            TDI->SetLargestPossibleRegion( m_UpsampledImageRegion );
+            TDI->SetBufferedRegion( m_UpsampledImageRegion );
+            TDI->SetRequestedRegion( m_UpsampledImageRegion );
+            TDI->Allocate();
+            TDI->FillBuffer(0);
+            itk::TractDensityImageFilter< ItkDoubleImgType >::Pointer tdiFilter = itk::TractDensityImageFilter< ItkDoubleImgType >::New();
+            tdiFilter->SetFiberBundle(m_FiberBundleTransformed);
+            tdiFilter->SetBinaryOutput(false);
+            tdiFilter->SetOutputAbsoluteValues(false);
+            tdiFilter->SetInputImage(TDI);
+            tdiFilter->SetUseImageGeometry(true);
+            tdiFilter->SetDoFiberResampling(false);
+            tdiFilter->Update();
+            TDI = tdiFilter->GetOutput();
+
             // generate fiber signal (if there are any fiber models present)
             if (!m_Parameters.m_FiberModelList.empty())
                 for( int i=0; i<numFibers; i++ )
                 {
                     float fiberWeight = m_FiberBundleTransformed->GetFiberWeight(i);
                     vtkCell* cell = fiberPolyData->GetCell(i);
                     int numPoints = cell->GetNumberOfPoints();
                     vtkPoints* points = cell->GetPoints();
 
                     if (numPoints<2)
                         continue;
 
                     for( int j=0; j<numPoints; j++)
                     {
                         if (this->GetAbortGenerateData())
                         {
                             m_StatusText += "\n"+this->GetTime()+" > Simulation aborted\n";
                             return;
                         }
 
                         double* temp = points->GetPoint(j);
                         itk::Point<float, 3> vertex = GetItkPoint(temp);
                         itk::Vector<double> v = GetItkVector(temp);
 
                         itk::Vector<double, 3> dir(3);
                         if (j<numPoints-1)
                             dir = GetItkVector(points->GetPoint(j+1))-v;
                         else
                             dir = v-GetItkVector(points->GetPoint(j-1));
 
                         if (dir.GetSquaredNorm()<0.0001 || dir[0]!=dir[0] || dir[1]!=dir[1] || dir[2]!=dir[2])
                             continue;
 
                         itk::Index<3> idx;
                         itk::ContinuousIndex<float, 3> contIndex;
                         m_MaskImage->TransformPhysicalPointToIndex(vertex, idx);
                         m_MaskImage->TransformPhysicalPointToContinuousIndex(vertex, contIndex);
 
                         if (!m_MaskImage->GetLargestPossibleRegion().IsInside(idx) || m_MaskImage->GetPixel(idx)<=0)
                             continue;
 
+                        double TdCorrectionFactor = 1;
+                        if (m_HelperTdiTransformed.IsNotNull())
+                        {
+                            double TD = TDI->GetPixel(idx);
+                            itk::Index<3> idx2;
+                            m_HelperTdiTransformed->TransformPhysicalPointToIndex(vertex, idx2);
+                            double HTD = m_HelperTdiTransformed->GetPixel(idx2);
+                            if (TD>0.00001)
+                                TdCorrectionFactor = sqrt(HTD)/TD;
+                        }
+
                         // generate signal for each fiber compartment
                         for (int k=0; k<numFiberCompartments; k++)
                         {
                             m_Parameters.m_FiberModelList[k]->SetFiberDirection(dir);
                             DoubleDwiType::PixelType pix = m_CompartmentImages.at(k)->GetPixel(idx);
-                            pix[g] += fiberWeight*segmentVolume*m_Parameters.m_FiberModelList[k]->SimulateMeasurement(g);
+                            pix[g] += TdCorrectionFactor*fiberWeight*segmentVolume*m_Parameters.m_FiberModelList[k]->SimulateMeasurement(g);
 
                             m_CompartmentImages.at(k)->SetPixel(idx, pix);
                         }
 
                         // update fiber volume image
-                        double vol = intraAxonalVolumeImage->GetPixel(idx) + segmentVolume*fiberWeight;
+                        double vol = intraAxonalVolumeImage->GetPixel(idx) + segmentVolume*fiberWeight*TdCorrectionFactor;
                         intraAxonalVolumeImage->SetPixel(idx, vol);
                         if (g==0 && vol>maxVolume)
                             maxVolume = vol;
                     }
 
                     // progress report
                     ++disp;
                     unsigned long newTick = 50*disp.count()/disp.expected_count();
                     for (unsigned int tick = 0; tick<(newTick-lastTick); tick++)
                         m_StatusText += "*";
                     lastTick = newTick;
                 }
 
             // generate non-fiber signal
             ImageRegionIterator<ItkUcharImgType> it3(m_MaskImage, m_MaskImage->GetLargestPossibleRegion());
             double fact = 1;
             if (m_Parameters.m_SignalGen.m_AxonRadius<0.0001 || maxVolume>m_VoxelVolume)
                 fact = m_VoxelVolume/maxVolume;
             while(!it3.IsAtEnd())
             {
                 if (it3.Get()>0)
                 {
                     DoubleDwiType::IndexType index = it3.GetIndex();
 
                     // adjust intra-axonal signal to abtain an only-fiber voxel
                     if (fabs(fact-1.0)>0.0001)
+                    {
                         for (int i=0; i<numFiberCompartments; i++)
                         {
                             DoubleDwiType::PixelType pix = m_CompartmentImages.at(i)->GetPixel(index);
                             pix[g] *= fact;
                             m_CompartmentImages.at(i)->SetPixel(index, pix);
                         }
+                    }
 
                     // simulate other compartments
                     SimulateNonFiberSignal(index, intraAxonalVolumeImage->GetPixel(index)*fact, g);
                 }
                 ++it3;
             }
 
             // move fibers
             SimulateMotion(g);
         }
         break;
     }
     case (SignalGenerationParameters::MAIN_FIBER_DIRECTIONS): // use main fiber directions to determine voxel-wise diffusion directions
     {
         typedef itk::Image< itk::Vector< float, 3>, 3 >                                 ItkDirectionImage3DType;
         typedef itk::VectorContainer< unsigned int, ItkDirectionImage3DType::Pointer >  ItkDirectionImageContainerType;
 
         // calculate main fiber directions
         itk::TractsToVectorImageFilter<float>::Pointer fOdfFilter = itk::TractsToVectorImageFilter<float>::New();
         fOdfFilter->SetFiberBundle(m_FiberBundleTransformed);
         fOdfFilter->SetMaskImage(m_MaskImage);
         fOdfFilter->SetAngularThreshold(cos(m_Parameters.m_SignalGen.m_FiberSeparationThreshold*M_PI/180.0));
         fOdfFilter->SetNormalizeVectors(false);
         fOdfFilter->SetUseWorkingCopy(true);
         fOdfFilter->SetSizeThreshold(0);
         fOdfFilter->SetMaxNumDirections(3);
         fOdfFilter->Update();
         ItkDirectionImageContainerType::Pointer directionImageContainer = fOdfFilter->GetDirectionImageContainer();
 
         // allocate image storing intra-axonal volume fraction information
         ItkDoubleImgType::Pointer intraAxonalVolumeImage = ItkDoubleImgType::New();
         intraAxonalVolumeImage->SetSpacing( m_UpsampledSpacing );
         intraAxonalVolumeImage->SetOrigin( m_UpsampledOrigin );
         intraAxonalVolumeImage->SetDirection( m_Parameters.m_SignalGen.m_ImageDirection );
         intraAxonalVolumeImage->SetLargestPossibleRegion( m_UpsampledImageRegion );
         intraAxonalVolumeImage->SetBufferedRegion( m_UpsampledImageRegion );
         intraAxonalVolumeImage->SetRequestedRegion( m_UpsampledImageRegion );
         intraAxonalVolumeImage->Allocate();
         intraAxonalVolumeImage->FillBuffer(0);
 
         // determine intra-axonal volume fraction using the tract density
         itk::TractDensityImageFilter< ItkDoubleImgType >::Pointer tdiFilter = itk::TractDensityImageFilter< ItkDoubleImgType >::New();
         tdiFilter->SetFiberBundle(m_FiberBundleTransformed);
         tdiFilter->SetBinaryOutput(false);
         tdiFilter->SetOutputAbsoluteValues(false);
         tdiFilter->SetInputImage(intraAxonalVolumeImage);
         tdiFilter->SetUseImageGeometry(true);
         tdiFilter->Update();
         intraAxonalVolumeImage = tdiFilter->GetOutput();
 
         m_StatusText += "0%   10   20   30   40   50   60   70   80   90   100%\n";
         m_StatusText += "|----|----|----|----|----|----|----|----|----|----|\n*";
         boost::progress_display disp(m_MaskImage->GetLargestPossibleRegion().GetNumberOfPixels()*m_Parameters.m_SignalGen.GetNumVolumes());
 
         for (unsigned int g=0; g<m_Parameters.m_SignalGen.GetNumVolumes(); g++)
         {
             // Set signal model random generator seeds to get same configuration in each voxel
             for (int i=0; i<m_Parameters.m_FiberModelList.size(); i++)
                 m_Parameters.m_FiberModelList.at(i)->SetSeed(signalModelSeed);
             for (int i=0; i<m_Parameters.m_NonFiberModelList.size(); i++)
                 m_Parameters.m_NonFiberModelList.at(i)->SetSeed(signalModelSeed);
 
             if (m_Parameters.m_SignalGen.m_DoAddMotion && g>0)  // if fibers have moved we need a new TDI and new directions
             {
                 fOdfFilter->SetFiberBundle(m_FiberBundleTransformed);
                 fOdfFilter->SetMaskImage(m_MaskImage);
                 fOdfFilter->Update();
                 directionImageContainer = fOdfFilter->GetDirectionImageContainer();
 
                 tdiFilter->SetFiberBundle(m_FiberBundleTransformed);
                 tdiFilter->Update();
                 intraAxonalVolumeImage = tdiFilter->GetOutput();
             }
 
             ImageRegionIterator< ItkUcharImgType > it(m_MaskImage, m_MaskImage->GetLargestPossibleRegion());
             while(!it.IsAtEnd())
             {
                 ++disp;
                 unsigned long newTick = 50*disp.count()/disp.expected_count();
                 for (unsigned int tick = 0; tick<(newTick-lastTick); tick++)
                     m_StatusText += "*";
                 lastTick = newTick;
 
                 if (this->GetAbortGenerateData())
                 {
                     m_StatusText += "\n"+this->GetTime()+" > Simulation aborted\n";
                     return;
                 }
 
                 if (it.Get()>0)
                 {
                     // generate fiber signal
                     for (int c=0; c<m_Parameters.m_FiberModelList.size(); c++)
                     {
                         int count = 0;
                         DoubleDwiType::PixelType pix = m_CompartmentImages.at(c)->GetPixel(it.GetIndex());
                         for (unsigned int i=0; i<directionImageContainer->Size(); i++)
                         {
                             itk::Vector< double, 3> dir;
                             dir.CastFrom(directionImageContainer->GetElement(i)->GetPixel(it.GetIndex()));
                             double norm = dir.GetNorm();
                             if (norm>0.0001)
                             {
                                 m_Parameters.m_FiberModelList.at(c)->SetFiberDirection(dir);
                                 pix[g] += m_Parameters.m_FiberModelList.at(c)->SimulateMeasurement(g)*norm;
                                 count++;
                             }
                         }
                         if (count>0)
                             pix[g] /= count;
                         pix[g] *= intraAxonalVolumeImage->GetPixel(it.GetIndex())*m_VoxelVolume;
                         m_CompartmentImages.at(c)->SetPixel(it.GetIndex(), pix);
                     }
 
                     // simulate other compartments
                     SimulateNonFiberSignal(it.GetIndex(), intraAxonalVolumeImage->GetPixel(it.GetIndex())*m_VoxelVolume, g);
                 }
                 ++it;
             }
 
             SimulateMotion(g);
         }
 
         itk::ImageFileWriter< ItkUcharImgType >::Pointer wr = itk::ImageFileWriter< ItkUcharImgType >::New();
         wr->SetInput(fOdfFilter->GetNumDirectionsImage());
         wr->SetFileName(mitk::IOUtil::GetTempPath()+"/NumDirections_MainFiberDirections.nrrd");
         wr->Update();
         break;
     }
     case (SignalGenerationParameters::RANDOM_DIRECTIONS):
     {
         ItkUcharImgType::Pointer numDirectionsImage = ItkUcharImgType::New();
         numDirectionsImage->SetSpacing( m_UpsampledSpacing );
         numDirectionsImage->SetOrigin( m_UpsampledOrigin );
         numDirectionsImage->SetDirection( m_Parameters.m_SignalGen.m_ImageDirection );
         numDirectionsImage->SetLargestPossibleRegion( m_UpsampledImageRegion );
         numDirectionsImage->SetBufferedRegion( m_UpsampledImageRegion );
         numDirectionsImage->SetRequestedRegion( m_UpsampledImageRegion );
         numDirectionsImage->Allocate();
         numDirectionsImage->FillBuffer(0);
         double sepAngle = cos(m_Parameters.m_SignalGen.m_FiberSeparationThreshold*M_PI/180.0);
 
         m_StatusText += "0%   10   20   30   40   50   60   70   80   90   100%\n";
         m_StatusText += "|----|----|----|----|----|----|----|----|----|----|\n*";
         boost::progress_display disp(m_MaskImage->GetLargestPossibleRegion().GetNumberOfPixels());
         ImageRegionIterator<ItkUcharImgType> it(m_MaskImage, m_MaskImage->GetLargestPossibleRegion());
         while(!it.IsAtEnd())
         {
             ++disp;
             unsigned long newTick = 50*disp.count()/disp.expected_count();
             for (unsigned int tick = 0; tick<(newTick-lastTick); tick++)
                 m_StatusText += "*";
             lastTick = newTick;
 
             if (this->GetAbortGenerateData())
             {
                 m_StatusText += "\n"+this->GetTime()+" > Simulation aborted\n";
                 return;
             }
 
             if (it.Get()>0)
             {
                 int numFibs = m_RandGen->GetIntegerVariate(2)+1;
                 DoubleDwiType::PixelType pix = m_CompartmentImages.at(0)->GetPixel(it.GetIndex());
                 double volume = m_RandGen->GetVariateWithClosedRange(0.3);
 
                 //                double sum = 0;
                 std::vector< double > fractions;
                 for (int i=0; i<numFibs; i++)
                 {
                     //                    fractions.push_back(1);
                     fractions.push_back(0.5+m_RandGen->GetVariateWithClosedRange(0.5));
                     //                    sum += fractions.at(i);
                 }
                 //                for (int i=0; i<numFibs; i++)
                 //                    fractions[i] /= sum;
 
                 std::vector< itk::Vector<double, 3> > directions;
                 for (int i=0; i<numFibs; i++)
                 {
                     DoubleVectorType fib;
                     fib[0] = m_RandGen->GetVariateWithClosedRange(2)-1.0;
                     fib[1] = m_RandGen->GetVariateWithClosedRange(2)-1.0;
                     fib[2] = m_RandGen->GetVariateWithClosedRange(2)-1.0;
                     fib.Normalize();
 
                     double min = 0;
                     for (unsigned int d=0; d<directions.size(); d++)
                     {
                         double angle = fabs(fib*directions[d]);
                         if (angle>min)
                             min = angle;
                     }
                     if (min<sepAngle)
                     {
                         m_Parameters.m_FiberModelList.at(0)->SetFiberDirection(fib);
                         pix += m_Parameters.m_FiberModelList.at(0)->SimulateMeasurement()*fractions[i];
                         directions.push_back(fib);
                     }
                     else
                         i--;
                 }
                 pix *= (1-volume);
                 m_CompartmentImages.at(0)->SetPixel(it.GetIndex(), pix);
 
                 // CSF/GM
                 {
                     pix += volume*m_Parameters.m_NonFiberModelList.at(0)->SimulateMeasurement();
                 }
 
                 numDirectionsImage->SetPixel(it.GetIndex(), numFibs);
             }
             ++it;
         }
 
         itk::ImageFileWriter< ItkUcharImgType >::Pointer wr = itk::ImageFileWriter< ItkUcharImgType >::New();
         wr->SetInput(numDirectionsImage);
         wr->SetFileName(mitk::IOUtil::GetTempPath()+"/NumDirections_RandomDirections.nrrd");
         wr->Update();
     }
     }
 
     if (m_Logfile.is_open())
     {
         m_Logfile << "DONE";
         m_Logfile.close();
     }
     m_StatusText += "\n\n";
     if (this->GetAbortGenerateData())
     {
         m_StatusText += "\n"+this->GetTime()+" > Simulation aborted\n";
         return;
     }
 
     DoubleDwiType::Pointer doubleOutImage;
     if ( m_Parameters.m_SignalGen.m_SimulateKspaceAcquisition ) // do k-space stuff
     {
         m_StatusText += this->GetTime()+" > Adjusting complex signal\n";
         MITK_INFO << "Adjusting complex signal:";
 
         if (m_Parameters.m_SignalGen.m_DoSimulateRelaxation)
             m_StatusText += "Simulating signal relaxation\n";
         if (m_Parameters.m_SignalGen.m_FrequencyMap.IsNotNull())
             m_StatusText += "Simulating distortions\n";
         if (m_Parameters.m_SignalGen.m_DoAddGibbsRinging)
             m_StatusText += "Simulating ringing artifacts\n";
         if (m_Parameters.m_SignalGen.m_EddyStrength>0)
             m_StatusText += "Simulating eddy currents\n";
         if (m_Parameters.m_SignalGen.m_Spikes>0)
             m_StatusText += "Simulating spikes\n";
         if (m_Parameters.m_SignalGen.m_CroppingFactor<1.0)
             m_StatusText += "Simulating aliasing artifacts\n";
         if (m_Parameters.m_SignalGen.m_KspaceLineOffset>0)
             m_StatusText += "Simulating ghosts\n";
 
         doubleOutImage = DoKspaceStuff(m_CompartmentImages);
         m_Parameters.m_SignalGen.m_SignalScale = 1; // already scaled in DoKspaceStuff
     }
     else    // don't do k-space stuff, just sum compartments
     {
         m_StatusText += this->GetTime()+" > Summing compartments\n";
         MITK_INFO << "Summing compartments";
         doubleOutImage = m_CompartmentImages.at(0);
 
         for (unsigned int i=1; i<m_CompartmentImages.size(); i++)
         {
             itk::AddImageFilter< DoubleDwiType, DoubleDwiType, DoubleDwiType>::Pointer adder = itk::AddImageFilter< DoubleDwiType, DoubleDwiType, DoubleDwiType>::New();
             adder->SetInput1(doubleOutImage);
             adder->SetInput2(m_CompartmentImages.at(i));
             adder->Update();
             doubleOutImage = adder->GetOutput();
         }
     }
     if (this->GetAbortGenerateData())
     {
         m_StatusText += "\n"+this->GetTime()+" > Simulation aborted\n";
         return;
     }
 
     m_StatusText += this->GetTime()+" > Finalizing image\n";
     MITK_INFO << "Finalizing image";
     if (m_Parameters.m_SignalGen.m_SignalScale>1)
         m_StatusText += " Scaling signal\n";
     if (m_Parameters.m_NoiseModel!=NULL)
         m_StatusText += " Adding noise\n";
     unsigned int window = 0;
     unsigned int min = itk::NumericTraits<unsigned int>::max();
     ImageRegionIterator<OutputImageType> it4 (outImage, outImage->GetLargestPossibleRegion());
     DoubleDwiType::PixelType signal; signal.SetSize(m_Parameters.m_SignalGen.GetNumVolumes());
     boost::progress_display disp2(outImage->GetLargestPossibleRegion().GetNumberOfPixels());
 
     m_StatusText += "0%   10   20   30   40   50   60   70   80   90   100%\n";
     m_StatusText += "|----|----|----|----|----|----|----|----|----|----|\n*";
     lastTick = 0;
 
     while(!it4.IsAtEnd())
     {
         if (this->GetAbortGenerateData())
         {
             m_StatusText += "\n"+this->GetTime()+" > Simulation aborted\n";
             return;
         }
 
         ++disp2;
         unsigned long newTick = 50*disp2.count()/disp2.expected_count();
         for (unsigned long tick = 0; tick<(newTick-lastTick); tick++)
             m_StatusText += "*";
         lastTick = newTick;
 
         typename OutputImageType::IndexType index = it4.GetIndex();
         signal = doubleOutImage->GetPixel(index)*m_Parameters.m_SignalGen.m_SignalScale;
 
         if (m_Parameters.m_NoiseModel!=NULL)
             m_Parameters.m_NoiseModel->AddNoise(signal);
 
         for (unsigned int i=0; i<signal.Size(); i++)
         {
             if (signal[i]>0)
                 signal[i] = floor(signal[i]+0.5);
             else
                 signal[i] = ceil(signal[i]-0.5);
 
             if ( (!m_Parameters.m_SignalGen.IsBaselineIndex(i) || signal.Size()==1) && signal[i]>window)
                 window = signal[i];
             if ( (!m_Parameters.m_SignalGen.IsBaselineIndex(i) || signal.Size()==1) && signal[i]<min)
                 min = signal[i];
         }
         it4.Set(signal);
         ++it4;
     }
     window -= min;
     unsigned int level = window/2 + min;
     m_LevelWindow.SetLevelWindow(level, window);
     this->SetNthOutput(0, outImage);
 
     m_StatusText += "\n\n";
     m_StatusText += "Finished simulation\n";
     m_StatusText += "Simulation time: "+GetTime();
     m_TimeProbe.Stop();
 }
 
 template< class PixelType >
 void TractsToDWIImageFilter< PixelType >::SimulateMotion(int g)
 {
     if (m_Parameters.m_SignalGen.m_DoAddMotion && g<m_Parameters.m_SignalGen.GetNumVolumes()-1)
     {
         if (m_Parameters.m_SignalGen.m_DoRandomizeMotion)
         {
             m_FiberBundleTransformed = m_FiberBundleWorkingCopy->GetDeepCopy();
             m_Rotation[0] = m_RandGen->GetVariateWithClosedRange(m_Parameters.m_SignalGen.m_Rotation[0]*2)-m_Parameters.m_SignalGen.m_Rotation[0];
             m_Rotation[1] = m_RandGen->GetVariateWithClosedRange(m_Parameters.m_SignalGen.m_Rotation[1]*2)-m_Parameters.m_SignalGen.m_Rotation[1];
             m_Rotation[2] = m_RandGen->GetVariateWithClosedRange(m_Parameters.m_SignalGen.m_Rotation[2]*2)-m_Parameters.m_SignalGen.m_Rotation[2];
             m_Translation[0] = m_RandGen->GetVariateWithClosedRange(m_Parameters.m_SignalGen.m_Translation[0]*2)-m_Parameters.m_SignalGen.m_Translation[0];
             m_Translation[1] = m_RandGen->GetVariateWithClosedRange(m_Parameters.m_SignalGen.m_Translation[1]*2)-m_Parameters.m_SignalGen.m_Translation[1];
             m_Translation[2] = m_RandGen->GetVariateWithClosedRange(m_Parameters.m_SignalGen.m_Translation[2]*2)-m_Parameters.m_SignalGen.m_Translation[2];
         }
 
         // rotate mask image
         if (m_MaskImageSet)
         {
             ImageRegionIterator<ItkUcharImgType> maskIt(m_UpsampledMaskImage, m_UpsampledMaskImage->GetLargestPossibleRegion());
             m_MaskImage->FillBuffer(0);
 
             while(!maskIt.IsAtEnd())
             {
                 if (maskIt.Get()<=0)
                 {
                     ++maskIt;
                     continue;
                 }
 
                 DoubleDwiType::IndexType index = maskIt.GetIndex();
                 itk::Point<double, 3> point;
                 m_UpsampledMaskImage->TransformIndexToPhysicalPoint(index, point);
                 if (m_Parameters.m_SignalGen.m_DoRandomizeMotion)
                     point = m_FiberBundleWorkingCopy->TransformPoint(point.GetVnlVector(), m_Rotation[0],m_Rotation[1],m_Rotation[2],m_Translation[0],m_Translation[1],m_Translation[2]);
                 else
                     point = m_FiberBundleWorkingCopy->TransformPoint(point.GetVnlVector(), m_Rotation[0]*(g+1),m_Rotation[1]*(g+1),m_Rotation[2]*(g+1),m_Translation[0]*(g+1),m_Translation[1]*(g+1),m_Translation[2]*(g+1));
 
                 m_MaskImage->TransformPhysicalPointToIndex(point, index);
                 if (m_MaskImage->GetLargestPossibleRegion().IsInside(index))
                     m_MaskImage->SetPixel(index,100);
                 ++maskIt;
             }
+//            itk::ImageFileWriter<ItkUcharImgType>::Pointer wr = itk::ImageFileWriter<ItkUcharImgType>::New();
+//            wr->SetInput(m_MaskImage);
+//            wr->SetFileName("/local/MASK_transformed.nrrd");
+//            wr->Update();
+        }
+
+        if (m_HelperTdiUpsampled.IsNotNull())
+        {
+            ImageRegionIterator<ItkFloatImgType> maskIt(m_HelperTdiUpsampled, m_HelperTdiUpsampled->GetLargestPossibleRegion());
+            m_HelperTdiTransformed->FillBuffer(0);
+            m_HelperTdiCounter->FillBuffer(0);
+
+            while(!maskIt.IsAtEnd())
+            {
+                DoubleDwiType::IndexType index = maskIt.GetIndex();
+
+                itk::Point<double, 3> point;
+                m_HelperTdiUpsampled->TransformIndexToPhysicalPoint(index, point);
+                if (m_Parameters.m_SignalGen.m_DoRandomizeMotion)
+                    point = m_FiberBundleWorkingCopy->TransformPoint(point.GetVnlVector(), m_Rotation[0],m_Rotation[1],m_Rotation[2],m_Translation[0],m_Translation[1],m_Translation[2]);
+                else
+                    point = m_FiberBundleWorkingCopy->TransformPoint(point.GetVnlVector(), m_Rotation[0]*(g+1),m_Rotation[1]*(g+1),m_Rotation[2]*(g+1),m_Translation[0]*(g+1),m_Translation[1]*(g+1),m_Translation[2]*(g+1));
+
+                m_HelperTdiTransformed->TransformPhysicalPointToIndex(point, index);
+                if (m_HelperTdiTransformed->GetLargestPossibleRegion().IsInside(index) && m_MaskImage->GetPixel(index)>0)
+                {
+                    m_HelperTdiTransformed->SetPixel(index, m_HelperTdiTransformed->GetPixel(index)+maskIt.Get());
+                    m_HelperTdiCounter->SetPixel(index, m_HelperTdiCounter->GetPixel(index)+1);
+                }
+                ++maskIt;
+            }
+
+            ImageRegionIterator<ItkFloatImgType> maskIt2(m_HelperTdiTransformed, m_HelperTdiTransformed->GetLargestPossibleRegion());
+            while(!maskIt2.IsAtEnd())
+            {
+                DoubleDwiType::IndexType index = maskIt2.GetIndex();
+                if (m_HelperTdiCounter->GetPixel(index)>0)
+                {
+                    m_HelperTdiTransformed->SetPixel(index, maskIt2.Get()/m_HelperTdiCounter->GetPixel(index));
+                }
+                ++maskIt2;
+            }
+
+            itk::ImageFileWriter<ItkFloatImgType>::Pointer wr = itk::ImageFileWriter<ItkFloatImgType>::New();
+            wr->SetInput(m_HelperTdiTransformed);
+            wr->SetFileName("/local/TDI_transformed.nrrd");
+            wr->Update();
         }
 
         // rotate fibers
         if (m_Logfile.is_open())
         {
             m_Logfile << g+1 << " rotation: " << m_Rotation[0] << "," << m_Rotation[1] << "," << m_Rotation[2] << ";";
             m_Logfile << " translation: " << m_Translation[0] << "," << m_Translation[1] << "," << m_Translation[2] << "\n";
         }
         m_FiberBundleTransformed->TransformFibers(m_Rotation[0],m_Rotation[1],m_Rotation[2],m_Translation[0],m_Translation[1],m_Translation[2]);
     }
 }
 
 template< class PixelType >
 void TractsToDWIImageFilter< PixelType >::SimulateNonFiberSignal(ItkUcharImgType::IndexType index, double intraAxonalVolume, int g)
 {
     int numFiberCompartments = m_Parameters.m_FiberModelList.size();
     int numNonFiberCompartments = m_Parameters.m_NonFiberModelList.size();
 
     if (intraAxonalVolume>0.0001 && m_Parameters.m_SignalGen.m_DoDisablePartialVolume)  // only fiber in voxel
     {
         DoubleDwiType::PixelType pix = m_CompartmentImages.at(0)->GetPixel(index);
         if (g>=0)
             pix[g] *= m_VoxelVolume/intraAxonalVolume;
         else
             pix *= m_VoxelVolume/intraAxonalVolume;
         m_CompartmentImages.at(0)->SetPixel(index, pix);
         m_VolumeFractions.at(0)->SetPixel(index, 1);
         for (int i=1; i<numFiberCompartments; i++)
         {
             DoubleDwiType::PixelType pix = m_CompartmentImages.at(i)->GetPixel(index);
             if (g>=0)
                 pix[g] = 0.0;
             else
                 pix.Fill(0.0);
             m_CompartmentImages.at(i)->SetPixel(index, pix);
         }
     }
     else
     {
         m_VolumeFractions.at(0)->SetPixel(index, intraAxonalVolume/m_VoxelVolume);
 
         itk::Point<double, 3> point;
         m_MaskImage->TransformIndexToPhysicalPoint(index, point);
         if (m_Parameters.m_SignalGen.m_DoAddMotion)
         {
             if (m_Parameters.m_SignalGen.m_DoRandomizeMotion && g>0)
                 point = m_FiberBundleWorkingCopy->TransformPoint(point.GetVnlVector(), -m_Rotation[0],-m_Rotation[1],-m_Rotation[2],-m_Translation[0],-m_Translation[1],-m_Translation[2]);
             else if (g>=0)
                 point = m_FiberBundleWorkingCopy->TransformPoint(point.GetVnlVector(), -m_Rotation[0]*g,-m_Rotation[1]*g,-m_Rotation[2]*g,-m_Translation[0]*g,-m_Translation[1]*g,-m_Translation[2]*g);
         }
 
         if (m_Parameters.m_SignalGen.m_DoDisablePartialVolume)
         {
             int maxVolumeIndex = 0;
             double maxWeight = 0;
             for (int i=0; i<numNonFiberCompartments; i++)
             {
                 double weight = 0;
                 if (numNonFiberCompartments>1)
                 {
+                    ItkUcharImgType::IndexType maskIndex;
+                    m_UpsampledMaskImage->TransformPhysicalPointToIndex(point, maskIndex);
+                    if (!m_UpsampledMaskImage->GetLargestPossibleRegion().IsInside(maskIndex) || m_UpsampledMaskImage->GetPixel(maskIndex)==0)
+                        continue;
                     DoubleDwiType::IndexType newIndex;
                     m_Parameters.m_NonFiberModelList[i]->GetVolumeFractionImage()->TransformPhysicalPointToIndex(point, newIndex);
                     if (!m_Parameters.m_NonFiberModelList[i]->GetVolumeFractionImage()->GetLargestPossibleRegion().IsInside(newIndex))
                         continue;
                     weight = m_Parameters.m_NonFiberModelList[i]->GetVolumeFractionImage()->GetPixel(newIndex);
                 }
 
                 if (weight>maxWeight)
                 {
                     maxWeight = weight;
                     maxVolumeIndex = i;
                 }
             }
             DoubleDwiType::Pointer doubleDwi = m_CompartmentImages.at(maxVolumeIndex+numFiberCompartments);
             DoubleDwiType::PixelType pix = doubleDwi->GetPixel(index);
 
             if (g>=0)
                 pix[g] += m_Parameters.m_NonFiberModelList[maxVolumeIndex]->SimulateMeasurement(g);
             else
                 pix += m_Parameters.m_NonFiberModelList[maxVolumeIndex]->SimulateMeasurement();
             doubleDwi->SetPixel(index, pix);
             m_VolumeFractions.at(maxVolumeIndex+numFiberCompartments)->SetPixel(index, 1);
         }
         else
         {
+//            double extraAxonalVolume = m_VoxelVolume-intraAxonalVolume;    // non-fiber volume
+//            if (extraAxonalVolume<0)
+//                extraAxonalVolume = 0;
+
+//            double interAxonalVolume = 0;
+//            if (numFiberCompartments>1)
+//                interAxonalVolume = 0.5*intraAxonalVolume;   // inter-axonal fraction of non fiber compartment scales linearly with f
+
+//            double other = extraAxonalVolume - interAxonalVolume;        // rest of compartment
+//            if (other<0)
+//            {
+//                other = 0;
+//                interAxonalVolume = extraAxonalVolume;
+//            }
+//            double singleinter = interAxonalVolume/(numFiberCompartments-1);
+
             double extraAxonalVolume = m_VoxelVolume-intraAxonalVolume;    // non-fiber volume
+            if (extraAxonalVolume<0)
+                extraAxonalVolume = 0;
             double interAxonalVolume = 0;
             if (numFiberCompartments>1)
                 interAxonalVolume = extraAxonalVolume * intraAxonalVolume/m_VoxelVolume;   // inter-axonal fraction of non fiber compartment scales linearly with f
             double other = extraAxonalVolume - interAxonalVolume;        // rest of compartment
+            if (other<0)
+                other = 0;
             double singleinter = interAxonalVolume/(numFiberCompartments-1);
 
             // adjust non-fiber and intra-axonal signal
             for (int i=1; i<numFiberCompartments; i++)
             {
                 DoubleDwiType::PixelType pix = m_CompartmentImages.at(i)->GetPixel(index);
                 if (intraAxonalVolume>0)    // remove scaling by intra-axonal volume from inter-axonal compartment
                 {
                     if (g>=0)
                         pix[g] /= intraAxonalVolume;
                     else
                         pix /= intraAxonalVolume;
                 }
                 if (g>=0)
                     pix[g] *= singleinter;
                 else
                     pix *= singleinter;
                 m_CompartmentImages.at(i)->SetPixel(index, pix);
                 m_VolumeFractions.at(i)->SetPixel(index, singleinter/m_VoxelVolume);
             }
 
             for (int i=0; i<numNonFiberCompartments; i++)
             {
                 double weight = 1;
                 if (numNonFiberCompartments>1)
                 {
+                    ItkUcharImgType::IndexType maskIndex;
+                    m_UpsampledMaskImage->TransformPhysicalPointToIndex(point, maskIndex);
+                    if (!m_UpsampledMaskImage->GetLargestPossibleRegion().IsInside(maskIndex) || m_UpsampledMaskImage->GetPixel(maskIndex)==0)
+                        continue;
                     DoubleDwiType::IndexType newIndex;
                     m_Parameters.m_NonFiberModelList[i]->GetVolumeFractionImage()->TransformPhysicalPointToIndex(point, newIndex);
                     if (!m_Parameters.m_NonFiberModelList[i]->GetVolumeFractionImage()->GetLargestPossibleRegion().IsInside(newIndex))
                         continue;
                     weight = m_Parameters.m_NonFiberModelList[i]->GetVolumeFractionImage()->GetPixel(newIndex);
                 }
 
                 DoubleDwiType::Pointer doubleDwi = m_CompartmentImages.at(i+numFiberCompartments);
                 DoubleDwiType::PixelType pix = doubleDwi->GetPixel(index);
 
                 if (g>=0)
                     pix[g] += m_Parameters.m_NonFiberModelList[i]->SimulateMeasurement(g)*other*weight;
                 else
                     pix += m_Parameters.m_NonFiberModelList[i]->SimulateMeasurement()*other*weight;
                 doubleDwi->SetPixel(index, pix);
                 m_VolumeFractions.at(i+numFiberCompartments)->SetPixel(index, other/m_VoxelVolume*weight);
             }
         }
     }
 }
 
 template< class PixelType >
 itk::Point<float, 3> TractsToDWIImageFilter< PixelType >::GetItkPoint(double point[3])
 {
     itk::Point<float, 3> itkPoint;
     itkPoint[0] = point[0];
     itkPoint[1] = point[1];
     itkPoint[2] = point[2];
     return itkPoint;
 }
 
 template< class PixelType >
 itk::Vector<double, 3> TractsToDWIImageFilter< PixelType >::GetItkVector(double point[3])
 {
     itk::Vector<double, 3> itkVector;
     itkVector[0] = point[0];
     itkVector[1] = point[1];
     itkVector[2] = point[2];
     return itkVector;
 }
 
 template< class PixelType >
 vnl_vector_fixed<double, 3> TractsToDWIImageFilter< PixelType >::GetVnlVector(double point[3])
 {
     vnl_vector_fixed<double, 3> vnlVector;
     vnlVector[0] = point[0];
     vnlVector[1] = point[1];
     vnlVector[2] = point[2];
     return vnlVector;
 }
 
 template< class PixelType >
 vnl_vector_fixed<double, 3> TractsToDWIImageFilter< PixelType >::GetVnlVector(Vector<float,3>& vector)
 {
     vnl_vector_fixed<double, 3> vnlVector;
     vnlVector[0] = vector[0];
     vnlVector[1] = vector[1];
     vnlVector[2] = vector[2];
     return vnlVector;
 }
 
 template< class PixelType >
 double TractsToDWIImageFilter< PixelType >::RoundToNearest(double num) {
     return (num > 0.0) ? floor(num + 0.5) : ceil(num - 0.5);
 }
 
 template< class PixelType >
 std::string TractsToDWIImageFilter< PixelType >::GetTime()
 {
     m_TimeProbe.Stop();
     unsigned long total = RoundToNearest(m_TimeProbe.GetTotal());
     unsigned long hours = total/3600;
     unsigned long minutes = (total%3600)/60;
     unsigned long seconds = total%60;
     std::string out = "";
     out.append(boost::lexical_cast<std::string>(hours));
     out.append(":");
     out.append(boost::lexical_cast<std::string>(minutes));
     out.append(":");
     out.append(boost::lexical_cast<std::string>(seconds));
     m_TimeProbe.Start();
     return out;
 }
 
 }
diff --git a/Modules/DiffusionImaging/FiberTracking/Algorithms/itkTractsToDWIImageFilter.h b/Modules/DiffusionImaging/FiberTracking/Algorithms/itkTractsToDWIImageFilter.h
index ee42dfddc7..737c8fd276 100755
--- a/Modules/DiffusionImaging/FiberTracking/Algorithms/itkTractsToDWIImageFilter.h
+++ b/Modules/DiffusionImaging/FiberTracking/Algorithms/itkTractsToDWIImageFilter.h
@@ -1,131 +1,139 @@
 /*===================================================================
 
 The Medical Imaging Interaction Toolkit (MITK)
 
 Copyright (c) German Cancer Research Center,
 Division of Medical and Biological Informatics.
 All rights reserved.
 
 This software is distributed WITHOUT ANY WARRANTY; without
 even the implied warranty of MERCHANTABILITY or FITNESS FOR
 A PARTICULAR PURPOSE.
 
 See LICENSE.txt or http://www.mitk.org for details.
 
 ===================================================================*/
 #ifndef __itkTractsToDWIImageFilter_h__
 #define __itkTractsToDWIImageFilter_h__
 
 #include <mitkFiberBundle.h>
 #include <itkVnlForwardFFTImageFilter.h>
 #include <itkVectorImage.h>
 #include <cmath>
 #include <mitkFiberfoxParameters.h>
 #include <itkTimeProbe.h>
 #include <mitkRawShModel.h>
 #include <itkAnalyticalDiffusionQballReconstructionImageFilter.h>
 
 namespace itk
 {
 
 /**
 * \brief Generates artificial diffusion weighted image volume from the input fiberbundle using a generic multicompartment model.
 * See "Fiberfox: Facilitating the creation of realistic white matter software phantoms" (DOI: 10.1002/mrm.25045) for details.
 */
 
 template< class PixelType >
 class TractsToDWIImageFilter : public ImageSource< itk::VectorImage< PixelType, 3 > >
 {
 
 public:
 
     typedef TractsToDWIImageFilter                          Self;
     typedef ImageSource< itk::VectorImage< PixelType, 3 > > Superclass;
     typedef SmartPointer< Self >                            Pointer;
     typedef SmartPointer< const Self >                      ConstPointer;
 
     typedef typename Superclass::OutputImageType                        OutputImageType;
     typedef itk::Image<double, 3>                                       ItkDoubleImgType;
+    typedef itk::Image<float, 3>                                        ItkFloatImgType;
     typedef itk::Image<unsigned char, 3>                                ItkUcharImgType;
     typedef mitk::FiberBundle::Pointer                                 FiberBundleType;
     typedef itk::VectorImage< double, 3 >                               DoubleDwiType;
     typedef itk::Matrix<double, 3, 3>                                   MatrixType;
     typedef itk::Image< double, 2 >                                     SliceType;
     typedef itk::VnlForwardFFTImageFilter<SliceType>::OutputImageType   ComplexSliceType;
     typedef itk::Vector< double,3>                                      DoubleVectorType;
 
     itkFactorylessNewMacro(Self)
     itkCloneMacro(Self)
     itkTypeMacro( TractsToDWIImageFilter, ImageSource )
 
     /** Input */
     itkSetMacro( FiberBundle, FiberBundleType )             ///< Input fiber bundle
     itkSetMacro( UseConstantRandSeed, bool )                ///< Seed for random generator.
     void SetParameters( FiberfoxParameters<double> param )  ///< Simulation parameters.
     { m_Parameters = param; }
+    itkSetMacro( HelperTdi, ItkFloatImgType::Pointer )
 
     /** Output */
     FiberfoxParameters<double> GetParameters(){ return m_Parameters; }
     std::vector< ItkDoubleImgType::Pointer > GetVolumeFractions() ///< one double image for each compartment containing the corresponding volume fraction per voxel
     { return m_VolumeFractions; }
     mitk::LevelWindow GetLevelWindow(){ return m_LevelWindow; }
     itkGetMacro( StatusText, std::string )
 
     void GenerateData();
 
 protected:
 
     TractsToDWIImageFilter();
     virtual ~TractsToDWIImageFilter();
     itk::Point<float, 3> GetItkPoint(double point[3]);
     itk::Vector<double, 3> GetItkVector(double point[3]);
     vnl_vector_fixed<double, 3> GetVnlVector(double point[3]);
     vnl_vector_fixed<double, 3> GetVnlVector(Vector< float, 3 >& vector);
     double RoundToNearest(double num);
     std::string GetTime();
 
     /** Transform generated image compartment by compartment, channel by channel and slice by slice using DFT and add k-space artifacts. */
     DoubleDwiType::Pointer DoKspaceStuff(std::vector< DoubleDwiType::Pointer >& images);
 
     /** Generate signal of non-fiber compartments. */
     void SimulateNonFiberSignal(ItkUcharImgType::IndexType index, double intraAxonalVolume, int g=-1);
 
     /** Move fibers to simulate headmotion */
     void SimulateMotion(int g=-1);
 
     // input
     mitk::FiberfoxParameters<double>            m_Parameters;
     FiberBundleType                             m_FiberBundle;
 
     // output
     mitk::LevelWindow                           m_LevelWindow;
     std::vector< ItkDoubleImgType::Pointer >    m_VolumeFractions;
     std::string                                 m_StatusText;
 
     // MISC
     itk::TimeProbe                              m_TimeProbe;
     bool                                        m_UseConstantRandSeed;
     bool                                        m_MaskImageSet;
     ofstream                                    m_Logfile;
 
     // signal generation
     FiberBundleType                             m_FiberBundleWorkingCopy;   ///< we work on an upsampled version of the input bundle
     FiberBundleType                             m_FiberBundleTransformed;   ///< transformed bundle simulating headmotion
     itk::Vector<double,3>                       m_UpsampledSpacing;
     itk::Point<double,3>                        m_UpsampledOrigin;
     ImageRegion<3>                              m_UpsampledImageRegion;
     double                                      m_VoxelVolume;
     std::vector< DoubleDwiType::Pointer >       m_CompartmentImages;
     ItkUcharImgType::Pointer                    m_MaskImage;                ///< copy of mask image (changes for each motion step)
     ItkUcharImgType::Pointer                    m_UpsampledMaskImage;       ///< helper image for motion simulation
     DoubleVectorType                            m_Rotation;
     DoubleVectorType                            m_Translation;
     itk::Statistics::MersenneTwisterRandomVariateGenerator::Pointer m_RandGen;
+
+    // TEMP
+    ItkFloatImgType::Pointer                    m_HelperTdi;
+    ItkFloatImgType::Pointer                    m_HelperTdiUpsampled;
+    ItkFloatImgType::Pointer                    m_HelperTdiTransformed;
+    ItkUcharImgType::Pointer                    m_HelperTdiCounter;
 };
 }
 
 #ifndef ITK_MANUAL_INSTANTIATION
 #include "itkTractsToDWIImageFilter.cpp"
 #endif
 
 #endif
diff --git a/Plugins/org.mitk.gui.qt.basicimageprocessing/src/internal/QmitkBasicImageProcessingView.cpp b/Plugins/org.mitk.gui.qt.basicimageprocessing/src/internal/QmitkBasicImageProcessingView.cpp
index f20b95dbf6..284f49bd92 100644
--- a/Plugins/org.mitk.gui.qt.basicimageprocessing/src/internal/QmitkBasicImageProcessingView.cpp
+++ b/Plugins/org.mitk.gui.qt.basicimageprocessing/src/internal/QmitkBasicImageProcessingView.cpp
@@ -1,1354 +1,1387 @@
 /*===================================================================
 
 The Medical Imaging Interaction Toolkit (MITK)
 
 Copyright (c) German Cancer Research Center,
 Division of Medical and Biological Informatics.
 All rights reserved.
 
 This software is distributed WITHOUT ANY WARRANTY; without
 even the implied warranty of MERCHANTABILITY or FITNESS FOR
 A PARTICULAR PURPOSE.
 
 See LICENSE.txt or http://www.mitk.org for details.
 
 ===================================================================*/
 
 #include "QmitkBasicImageProcessingView.h"
 
 // QT includes (GUI)
 #include <qlabel.h>
 #include <qspinbox.h>
 #include <qpushbutton.h>
 #include <qcheckbox.h>
 #include <qgroupbox.h>
 #include <qradiobutton.h>
 #include <qmessagebox.h>
 
 // Berry includes (selection service)
 #include <berryISelectionService.h>
 #include <berryIWorkbenchWindow.h>
 
 // MITK includes (GUI)
 #include "QmitkStdMultiWidget.h"
 #include "QmitkDataNodeSelectionProvider.h"
 #include "mitkDataNodeObject.h"
 
 // MITK includes (general)
 #include "mitkNodePredicateDataType.h"
 #include "mitkNodePredicateDimension.h"
 #include "mitkNodePredicateAnd.h"
 #include "mitkImageTimeSelector.h"
 #include "mitkVectorImageMapper2D.h"
 #include "mitkProperties.h"
 
 // Includes for image casting between ITK and MITK
 #include "mitkImageCast.h"
 #include "mitkITKImageImport.h"
 
 // ITK includes (general)
 #include <itkVectorImage.h>
 #include <itkImageFileWriter.h>
 
 // Morphological Operations
 #include <itkBinaryBallStructuringElement.h>
 #include <itkGrayscaleDilateImageFilter.h>
 #include <itkGrayscaleErodeImageFilter.h>
 #include <itkGrayscaleMorphologicalOpeningImageFilter.h>
 #include <itkGrayscaleMorphologicalClosingImageFilter.h>
 
 // Smoothing
 #include <itkMedianImageFilter.h>
 #include <itkDiscreteGaussianImageFilter.h>
 #include <itkTotalVariationDenoisingImageFilter.h>
 
 // Threshold
 #include <itkBinaryThresholdImageFilter.h>
 
 // Inversion
 #include <itkInvertIntensityImageFilter.h>
 
 // Derivatives
 #include <itkGradientMagnitudeRecursiveGaussianImageFilter.h>
 #include <itkLaplacianImageFilter.h>
 #include <itkSobelEdgeDetectionImageFilter.h>
 
 // Resampling
 #include <itkResampleImageFilter.h>
 #include <itkNearestNeighborInterpolateImageFunction.h>
 #include <itkCastImageFilter.h>
 #include <itkLinearInterpolateImageFunction.h>
 
 // Image Arithmetics
 #include <itkAddImageFilter.h>
 #include <itkSubtractImageFilter.h>
 #include <itkMultiplyImageFilter.h>
 #include <itkDivideImageFilter.h>
 
 // Boolean operations
 #include <itkOrImageFilter.h>
 #include <itkAndImageFilter.h>
 #include <itkXorImageFilter.h>
 
 // Flip Image
 #include <itkFlipImageFilter.h>
 
 #include <itkRescaleIntensityImageFilter.h>
+#include <itkShiftScaleImageFilter.h>
 
 
 // Convenient Definitions
 typedef itk::Image<short, 3>                                                            ImageType;
 typedef itk::Image<unsigned char, 3>                                                    SegmentationImageType;
-typedef itk::Image<double, 3>                                                           FloatImageType;
+typedef itk::Image<double, 3>                                                           DoubleImageType;
 typedef itk::Image<itk::Vector<float,3>, 3>                                             VectorImageType;
 
 typedef itk::BinaryBallStructuringElement<ImageType::PixelType, 3>                      BallType;
 typedef itk::GrayscaleDilateImageFilter<ImageType, ImageType, BallType>                 DilationFilterType;
 typedef itk::GrayscaleErodeImageFilter<ImageType, ImageType, BallType>                  ErosionFilterType;
 typedef itk::GrayscaleMorphologicalOpeningImageFilter<ImageType, ImageType, BallType>   OpeningFilterType;
 typedef itk::GrayscaleMorphologicalClosingImageFilter<ImageType, ImageType, BallType>   ClosingFilterType;
 
 typedef itk::MedianImageFilter< ImageType, ImageType >                                  MedianFilterType;
 typedef itk::DiscreteGaussianImageFilter< ImageType, ImageType>                         GaussianFilterType;
-typedef itk::TotalVariationDenoisingImageFilter<FloatImageType, FloatImageType>         TotalVariationFilterType;
+typedef itk::TotalVariationDenoisingImageFilter<DoubleImageType, DoubleImageType>         TotalVariationFilterType;
 typedef itk::TotalVariationDenoisingImageFilter<VectorImageType, VectorImageType>       VectorTotalVariationFilterType;
 
 typedef itk::BinaryThresholdImageFilter< ImageType, ImageType >                         ThresholdFilterType;
 typedef itk::InvertIntensityImageFilter< ImageType, ImageType >                         InversionFilterType;
 
 typedef itk::GradientMagnitudeRecursiveGaussianImageFilter< ImageType, ImageType >      GradientFilterType;
-typedef itk::LaplacianImageFilter< FloatImageType, FloatImageType >                     LaplacianFilterType;
-typedef itk::SobelEdgeDetectionImageFilter< FloatImageType, FloatImageType >            SobelFilterType;
+typedef itk::LaplacianImageFilter< DoubleImageType, DoubleImageType >                     LaplacianFilterType;
+typedef itk::SobelEdgeDetectionImageFilter< DoubleImageType, DoubleImageType >            SobelFilterType;
 
 typedef itk::ResampleImageFilter< ImageType, ImageType >                                ResampleImageFilterType;
 typedef itk::ResampleImageFilter< ImageType, ImageType >                                ResampleImageFilterType2;
-typedef itk::CastImageFilter< ImageType, FloatImageType >                               ImagePTypeToFloatPTypeCasterType;
+typedef itk::CastImageFilter< ImageType, DoubleImageType >                               ImagePTypeToFloatPTypeCasterType;
 
 typedef itk::AddImageFilter< ImageType, ImageType, ImageType >                          AddFilterType;
 typedef itk::SubtractImageFilter< ImageType, ImageType, ImageType >                     SubtractFilterType;
 typedef itk::MultiplyImageFilter< ImageType, ImageType, ImageType >                     MultiplyFilterType;
-typedef itk::DivideImageFilter< ImageType, ImageType, FloatImageType >                  DivideFilterType;
+typedef itk::DivideImageFilter< ImageType, ImageType, DoubleImageType >                  DivideFilterType;
 
 typedef itk::OrImageFilter< ImageType, ImageType >                                      OrImageFilterType;
 typedef itk::AndImageFilter< ImageType, ImageType >                                     AndImageFilterType;
 typedef itk::XorImageFilter< ImageType, ImageType >                                     XorImageFilterType;
 
 typedef itk::FlipImageFilter< ImageType >                                               FlipImageFilterType;
 
 typedef itk::LinearInterpolateImageFunction< ImageType, double >                        LinearInterpolatorType;
 typedef itk::NearestNeighborInterpolateImageFunction< ImageType, double >               NearestInterpolatorType;
 
 
 QmitkBasicImageProcessing::QmitkBasicImageProcessing()
 : QmitkFunctionality(),
   m_Controls(NULL),
   m_SelectedImageNode(NULL),
   m_TimeStepperAdapter(NULL)
 {
 }
 
 QmitkBasicImageProcessing::~QmitkBasicImageProcessing()
 {
   //berry::ISelectionService* s = GetSite()->GetWorkbenchWindow()->GetSelectionService();
   //if(s)
   //  s->RemoveSelectionListener(m_SelectionListener);
 }
 
 void QmitkBasicImageProcessing::CreateQtPartControl(QWidget *parent)
 {
   if (m_Controls == NULL)
   {
     m_Controls = new Ui::QmitkBasicImageProcessingViewControls;
     m_Controls->setupUi(parent);
     this->CreateConnections();
 
 
     //setup predictaes for combobox
 
     mitk::NodePredicateDimension::Pointer dimensionPredicate = mitk::NodePredicateDimension::New(3);
     mitk::NodePredicateDataType::Pointer imagePredicate = mitk::NodePredicateDataType::New("Image");
     m_Controls->m_ImageSelector2->SetDataStorage(this->GetDefaultDataStorage());
     m_Controls->m_ImageSelector2->SetPredicate(mitk::NodePredicateAnd::New(dimensionPredicate, imagePredicate));
   }
   m_Controls->gbTwoImageOps->hide();
 
   m_SelectedImageNode = mitk::DataStorageSelection::New(this->GetDefaultDataStorage(), false);
 }
 
 void QmitkBasicImageProcessing::CreateConnections()
 {
   if ( m_Controls )
   {
     connect( (QObject*)(m_Controls->cbWhat1), SIGNAL( activated(int) ), this, SLOT( SelectAction(int) ) );
     connect( (QObject*)(m_Controls->btnDoIt), SIGNAL(clicked()),(QObject*) this, SLOT(StartButtonClicked()));
-
     connect( (QObject*)(m_Controls->cbWhat2), SIGNAL( activated(int) ), this, SLOT( SelectAction2(int) ) );
     connect( (QObject*)(m_Controls->btnDoIt2), SIGNAL(clicked()),(QObject*) this, SLOT(StartButton2Clicked()));
-
     connect( (QObject*)(m_Controls->rBOneImOp), SIGNAL( clicked() ), this, SLOT( ChangeGUI() ) );
     connect( (QObject*)(m_Controls->rBTwoImOp), SIGNAL( clicked() ), this, SLOT( ChangeGUI() ) );
-
     connect( (QObject*)(m_Controls->cbParam4), SIGNAL( activated(int) ), this, SLOT( SelectInterpolator(int) ) );
   }
 
   m_TimeStepperAdapter = new QmitkStepperAdapter((QObject*) m_Controls->sliceNavigatorTime,
     GetActiveStdMultiWidget()->GetTimeNavigationController()->GetTime(), "sliceNavigatorTimeFromBIP");
 }
 
 void QmitkBasicImageProcessing::Activated()
 {
   QmitkFunctionality::Activated();
 
   this->m_Controls->cbWhat1->clear();
   this->m_Controls->cbWhat1->insertItem( NOACTIONSELECTED, "Please select operation");
   this->m_Controls->cbWhat1->insertItem( CATEGORY_DENOISING, "--- Denoising ---");
   this->m_Controls->cbWhat1->insertItem( GAUSSIAN, "Gaussian");
   this->m_Controls->cbWhat1->insertItem( MEDIAN, "Median");
   this->m_Controls->cbWhat1->insertItem( TOTALVARIATION, "Total Variation");
   this->m_Controls->cbWhat1->insertItem( CATEGORY_MORPHOLOGICAL, "--- Morphological ---");
   this->m_Controls->cbWhat1->insertItem( DILATION, "Dilation");
   this->m_Controls->cbWhat1->insertItem( EROSION, "Erosion");
   this->m_Controls->cbWhat1->insertItem( OPENING, "Opening");
   this->m_Controls->cbWhat1->insertItem( CLOSING, "Closing");
   this->m_Controls->cbWhat1->insertItem( CATEGORY_EDGE_DETECTION, "--- Edge Detection ---");
   this->m_Controls->cbWhat1->insertItem( GRADIENT, "Gradient");
   this->m_Controls->cbWhat1->insertItem( LAPLACIAN, "Laplacian (2nd Derivative)");
   this->m_Controls->cbWhat1->insertItem( SOBEL, "Sobel Operator");
   this->m_Controls->cbWhat1->insertItem( CATEGORY_MISC, "--- Misc ---");
   this->m_Controls->cbWhat1->insertItem( THRESHOLD, "Threshold");
   this->m_Controls->cbWhat1->insertItem( INVERSION, "Image Inversion");
   this->m_Controls->cbWhat1->insertItem( DOWNSAMPLING, "Downsampling");
   this->m_Controls->cbWhat1->insertItem( FLIPPING, "Flipping");
   this->m_Controls->cbWhat1->insertItem( RESAMPLING, "Resample to");
-  this->m_Controls->cbWhat1->insertItem( RESCALE, "Rescale image values");
+  this->m_Controls->cbWhat1->insertItem( RESCALE, "Rescale values to interval");
+  this->m_Controls->cbWhat1->insertItem( RESCALE2, "Rescale values by scalar");
 
   this->m_Controls->cbWhat2->clear();
   this->m_Controls->cbWhat2->insertItem( TWOIMAGESNOACTIONSELECTED, "Please select on operation" );
   this->m_Controls->cbWhat2->insertItem( CATEGORY_ARITHMETIC, "--- Arithmetric operations ---" );
   this->m_Controls->cbWhat2->insertItem( ADD, "Add to Image 1:" );
   this->m_Controls->cbWhat2->insertItem( SUBTRACT, "Subtract from Image 1:" );
   this->m_Controls->cbWhat2->insertItem( MULTIPLY, "Multiply with Image 1:" );
   this->m_Controls->cbWhat2->insertItem( RESAMPLE_TO, "Resample Image 1 to fit geometry:" );
   this->m_Controls->cbWhat2->insertItem( DIVIDE, "Divide Image 1 by:" );
   this->m_Controls->cbWhat2->insertItem( CATEGORY_BOOLEAN, "--- Boolean operations ---" );
   this->m_Controls->cbWhat2->insertItem( AND, "AND" );
   this->m_Controls->cbWhat2->insertItem( OR, "OR" );
   this->m_Controls->cbWhat2->insertItem( XOR, "XOR" );
 
   this->m_Controls->cbParam4->clear();
   this->m_Controls->cbParam4->insertItem( LINEAR, "Linear" );
   this->m_Controls->cbParam4->insertItem( NEAREST, "Nearest neighbor" );
 
   m_Controls->dsbParam1->hide();
   m_Controls->dsbParam2->hide();
   m_Controls->dsbParam3->hide();
   m_Controls->tlParam3->hide();
   m_Controls->tlParam4->hide();
   m_Controls->cbParam4->hide();
 }
 
 //datamanager selection changed
 void QmitkBasicImageProcessing::OnSelectionChanged(std::vector<mitk::DataNode*> nodes)
 {
   //any nodes there?
   if (!nodes.empty())
   {
   // reset GUI
 //  this->ResetOneImageOpPanel();
   m_Controls->sliceNavigatorTime->setEnabled(false);
   m_Controls->leImage1->setText("Select an Image in Data Manager");
   m_Controls->tlWhat1->setEnabled(false);
   m_Controls->cbWhat1->setEnabled(false);
   m_Controls->tlWhat2->setEnabled(false);
   m_Controls->cbWhat2->setEnabled(false);
 
   m_SelectedImageNode->RemoveAllNodes();
   //get the selected Node
   mitk::DataNode* _DataNode = nodes.front();
   *m_SelectedImageNode = _DataNode;
   //try to cast to image
   mitk::Image::Pointer tempImage = dynamic_cast<mitk::Image*>(m_SelectedImageNode->GetNode()->GetData());
 
     //no image
     if( tempImage.IsNull() || (tempImage->IsInitialized() == false) )
     {
       m_Controls->leImage1->setText("Not an image.");
       return;
     }
 
     //2D image
     if( tempImage->GetDimension() < 3)
     {
       m_Controls->leImage1->setText("2D images are not supported.");
       return;
     }
 
     //image
     m_Controls->leImage1->setText(QString(m_SelectedImageNode->GetNode()->GetName().c_str()));
 
     // button coding
     if ( tempImage->GetDimension() > 3 )
     {
       m_Controls->sliceNavigatorTime->setEnabled(true);
       m_Controls->tlTime->setEnabled(true);
     }
     m_Controls->tlWhat1->setEnabled(true);
     m_Controls->cbWhat1->setEnabled(true);
     m_Controls->tlWhat2->setEnabled(true);
     m_Controls->cbWhat2->setEnabled(true);
   }
 }
 
 void QmitkBasicImageProcessing::ChangeGUI()
 {
   if(m_Controls->rBOneImOp->isChecked())
   {
     m_Controls->gbTwoImageOps->hide();
     m_Controls->gbOneImageOps->show();
   }
   else if(m_Controls->rBTwoImOp->isChecked())
   {
     m_Controls->gbOneImageOps->hide();
     m_Controls->gbTwoImageOps->show();
   }
 }
 
 void QmitkBasicImageProcessing::ResetOneImageOpPanel()
 {
   m_Controls->tlParam1->setText("Param1");
   m_Controls->tlParam2->setText("Param2");
 
   m_Controls->cbWhat1->setCurrentIndex(0);
 
   m_Controls->tlTime->setEnabled(false);
 
   this->ResetParameterPanel();
 
   m_Controls->btnDoIt->setEnabled(false);
   m_Controls->cbHideOrig->setEnabled(false);
 }
 
 void QmitkBasicImageProcessing::ResetParameterPanel()
 {
   m_Controls->tlParam->setEnabled(false);
   m_Controls->tlParam1->setEnabled(false);
   m_Controls->tlParam2->setEnabled(false);
   m_Controls->tlParam3->setEnabled(false);
   m_Controls->tlParam4->setEnabled(false);
 
   m_Controls->sbParam1->setEnabled(false);
   m_Controls->sbParam2->setEnabled(false);
   m_Controls->dsbParam1->setEnabled(false);
   m_Controls->dsbParam2->setEnabled(false);
   m_Controls->dsbParam3->setEnabled(false);
   m_Controls->cbParam4->setEnabled(false);
   m_Controls->sbParam1->setValue(0);
   m_Controls->sbParam2->setValue(0);
   m_Controls->dsbParam1->setValue(0);
   m_Controls->dsbParam2->setValue(0);
   m_Controls->dsbParam3->setValue(0);
 
   m_Controls->sbParam1->show();
   m_Controls->sbParam2->show();
   m_Controls->dsbParam1->hide();
   m_Controls->dsbParam2->hide();
   m_Controls->dsbParam3->hide();
   m_Controls->cbParam4->hide();
   m_Controls->tlParam3->hide();
   m_Controls->tlParam4->hide();
 }
 
 void QmitkBasicImageProcessing::ResetTwoImageOpPanel()
 {
   m_Controls->cbWhat2->setCurrentIndex(0);
 
   m_Controls->tlImage2->setEnabled(false);
   m_Controls->m_ImageSelector2->setEnabled(false);
 
   m_Controls->btnDoIt2->setEnabled(false);
 }
 
 void QmitkBasicImageProcessing::SelectAction(int action)
 {
   if ( ! m_SelectedImageNode->GetNode() ) return;
 
   // Prepare GUI
   this->ResetParameterPanel();
   m_Controls->btnDoIt->setEnabled(false);
   m_Controls->cbHideOrig->setEnabled(false);
 
   QString text1 = "No Parameters";
   QString text2 = "No Parameters";
   QString text3 = "No Parameters";
   QString text4 = "No Parameters";
 
   if (action != 19)
   {
     m_Controls->dsbParam1->hide();
     m_Controls->dsbParam2->hide();
     m_Controls->dsbParam3->hide();
     m_Controls->tlParam3->hide();
     m_Controls->tlParam4->hide();
     m_Controls->sbParam1->show();
     m_Controls->sbParam2->show();
     m_Controls->cbParam4->hide();
   }
   // check which operation the user has selected and set parameters and GUI accordingly
   switch (action)
   {
   case 2:
     {
       m_SelectedAction = GAUSSIAN;
       m_Controls->tlParam1->setEnabled(true);
       m_Controls->sbParam1->setEnabled(true);
       text1 = "&Variance:";
 
       m_Controls->sbParam1->setMinimum( 0 );
       m_Controls->sbParam1->setMaximum( 200 );
       m_Controls->sbParam1->setValue( 2 );
       break;
     }
 
   case 3:
     {
       m_SelectedAction = MEDIAN;
       m_Controls->tlParam1->setEnabled(true);
       m_Controls->sbParam1->setEnabled(true);
       text1 = "&Radius:";
       m_Controls->sbParam1->setMinimum( 0 );
       m_Controls->sbParam1->setMaximum( 200 );
       m_Controls->sbParam1->setValue( 3 );
       break;
     }
 
   case 4:
     {
       m_SelectedAction = TOTALVARIATION;
       m_Controls->tlParam1->setEnabled(true);
       m_Controls->sbParam1->setEnabled(true);
       m_Controls->tlParam2->setEnabled(true);
       m_Controls->sbParam2->setEnabled(true);
       text1 = "Number Iterations:";
       text2 = "Regularization\n(Lambda/1000):";
       m_Controls->sbParam1->setMinimum( 1 );
       m_Controls->sbParam1->setMaximum( 1000 );
       m_Controls->sbParam1->setValue( 40 );
       m_Controls->sbParam2->setMinimum( 0 );
       m_Controls->sbParam2->setMaximum( 100000 );
       m_Controls->sbParam2->setValue( 1 );
       break;
     }
 
   case 6:
     {
       m_SelectedAction = DILATION;
       m_Controls->tlParam1->setEnabled(true);
       m_Controls->sbParam1->setEnabled(true);
       text1 = "&Radius:";
       m_Controls->sbParam1->setMinimum( 0 );
       m_Controls->sbParam1->setMaximum( 200 );
       m_Controls->sbParam1->setValue( 3 );
       break;
     }
 
   case 7:
     {
       m_SelectedAction = EROSION;
       m_Controls->tlParam1->setEnabled(true);
       m_Controls->sbParam1->setEnabled(true);
       text1 = "&Radius:";
       m_Controls->sbParam1->setMinimum( 0 );
       m_Controls->sbParam1->setMaximum( 200 );
       m_Controls->sbParam1->setValue( 3 );
       break;
     }
 
   case 8:
     {
       m_SelectedAction = OPENING;
       m_Controls->tlParam1->setEnabled(true);
       m_Controls->sbParam1->setEnabled(true);
       text1 = "&Radius:";
       m_Controls->sbParam1->setMinimum( 0 );
       m_Controls->sbParam1->setMaximum( 200 );
       m_Controls->sbParam1->setValue( 3 );
       break;
     }
 
   case 9:
     {
       m_SelectedAction = CLOSING;
       m_Controls->tlParam1->setEnabled(true);
       m_Controls->sbParam1->setEnabled(true);
       text1 = "&Radius:";
       m_Controls->sbParam1->setMinimum( 0 );
       m_Controls->sbParam1->setMaximum( 200 );
       m_Controls->sbParam1->setValue( 3 );
       break;
     }
 
   case 11:
     {
       m_SelectedAction = GRADIENT;
       m_Controls->tlParam1->setEnabled(true);
       m_Controls->sbParam1->setEnabled(true);
       text1 = "Sigma of Gaussian Kernel:\n(in Image Spacing Units)";
       m_Controls->sbParam1->setMinimum( 0 );
       m_Controls->sbParam1->setMaximum( 200 );
       m_Controls->sbParam1->setValue( 2 );
       break;
     }
 
   case 12:
     {
       m_SelectedAction = LAPLACIAN;
       break;
     }
 
   case 13:
     {
       m_SelectedAction = SOBEL;
       break;
     }
 
   case 15:
     {
       m_SelectedAction = THRESHOLD;
       m_Controls->tlParam1->setEnabled(true);
       m_Controls->sbParam1->setEnabled(true);
       m_Controls->tlParam2->setEnabled(true);
       m_Controls->sbParam2->setEnabled(true);
       text1 = "Lower threshold:";
       text2 = "Upper threshold:";
       m_Controls->sbParam1->setMinimum( -100000 );
       m_Controls->sbParam1->setMaximum( 100000 );
       m_Controls->sbParam1->setValue( 0 );
       m_Controls->sbParam2->setMinimum( -100000 );
       m_Controls->sbParam2->setMaximum( 100000 );
       m_Controls->sbParam2->setValue( 300 );
       break;
     }
 
   case 16:
     {
       m_SelectedAction = INVERSION;
       break;
     }
 
   case 17:
     {
       m_SelectedAction = DOWNSAMPLING;
       m_Controls->tlParam1->setEnabled(true);
       m_Controls->sbParam1->setEnabled(true);
       text1 = "Downsampling by Factor:";
       m_Controls->sbParam1->setMinimum( 1 );
       m_Controls->sbParam1->setMaximum( 100 );
       m_Controls->sbParam1->setValue( 2 );
       break;
     }
 
   case 18:
     {
       m_SelectedAction = FLIPPING;
       m_Controls->tlParam1->setEnabled(true);
       m_Controls->sbParam1->setEnabled(true);
       text1 = "Flip across axis:";
       m_Controls->sbParam1->setMinimum( 0 );
       m_Controls->sbParam1->setMaximum( 2 );
       m_Controls->sbParam1->setValue( 1 );
       break;
     }
 
   case 19:
     {
       m_SelectedAction = RESAMPLING;
       m_Controls->tlParam1->setEnabled(true);
       m_Controls->sbParam1->setEnabled(false);
       m_Controls->sbParam1->hide();
       m_Controls->dsbParam1->show();
       m_Controls->dsbParam1->setEnabled(true);
       m_Controls->tlParam2->setEnabled(true);
       m_Controls->sbParam2->setEnabled(false);
       m_Controls->sbParam2->hide();
       m_Controls->dsbParam2->show();
       m_Controls->dsbParam2->setEnabled(true);
       m_Controls->tlParam3->show();
       m_Controls->tlParam3->setEnabled(true);
       m_Controls->dsbParam3->show();
       m_Controls->dsbParam3->setEnabled(true);
       m_Controls->tlParam4->show();
       m_Controls->tlParam4->setEnabled(true);
       m_Controls->cbParam4->show();
       m_Controls->cbParam4->setEnabled(true);
 
       m_Controls->dsbParam1->setMinimum(0.01);
       m_Controls->dsbParam1->setMaximum(10.0);
       m_Controls->dsbParam1->setSingleStep(0.1);
       m_Controls->dsbParam1->setValue(0.3);
       m_Controls->dsbParam2->setMinimum(0.01);
       m_Controls->dsbParam2->setMaximum(10.0);
       m_Controls->dsbParam2->setSingleStep(0.1);
       m_Controls->dsbParam2->setValue(0.3);
       m_Controls->dsbParam3->setMinimum(0.01);
       m_Controls->dsbParam3->setMaximum(10.0);
       m_Controls->dsbParam3->setSingleStep(0.1);
       m_Controls->dsbParam3->setValue(1.5);
 
       text1 = "x-spacing:";
       text2 = "y-spacing:";
       text3 = "z-spacing:";
       text4 = "Interplation:";
       break;
     }
 
   case 20:
     {
       m_SelectedAction = RESCALE;
       m_Controls->dsbParam1->show();
       m_Controls->tlParam1->show();
       m_Controls->dsbParam1->setEnabled(true);
       m_Controls->tlParam1->setEnabled(true);
       m_Controls->dsbParam2->show();
       m_Controls->tlParam2->show();
       m_Controls->dsbParam2->setEnabled(true);
       m_Controls->tlParam2->setEnabled(true);
       text1 = "Output minimum:";
       text2 = "Output maximum:";
       break;
     }
+  case 21:
+  {
+      m_SelectedAction = RESCALE2;
+      m_Controls->dsbParam1->show();
+      m_Controls->tlParam1->show();
+      m_Controls->dsbParam1->setEnabled(true);
+      m_Controls->tlParam1->setEnabled(true);
+      text1 = "Scaling value:";
+      break;
+  }
 
   default: return;
   }
 
   m_Controls->tlParam->setEnabled(true);
   m_Controls->tlParam1->setText(text1);
   m_Controls->tlParam2->setText(text2);
   m_Controls->tlParam3->setText(text3);
   m_Controls->tlParam4->setText(text4);
 
   m_Controls->btnDoIt->setEnabled(true);
   m_Controls->cbHideOrig->setEnabled(true);
 }
 
 void QmitkBasicImageProcessing::StartButtonClicked()
 {
   if(!m_SelectedImageNode->GetNode()) return;
 
   this->BusyCursorOn();
 
   mitk::Image::Pointer newImage;
 
   try
   {
     newImage = dynamic_cast<mitk::Image*>(m_SelectedImageNode->GetNode()->GetData());
   }
   catch ( std::exception &e )
   {
   QString exceptionString = "An error occured during image loading:\n";
   exceptionString.append( e.what() );
     QMessageBox::warning( NULL, "Basic Image Processing", exceptionString , QMessageBox::Ok, QMessageBox::NoButton );
     this->BusyCursorOff();
     return;
   }
 
   // check if input image is valid, casting does not throw exception when casting from 'NULL-Object'
   if ( (! newImage) || (newImage->IsInitialized() == false) )
   {
     this->BusyCursorOff();
 
     QMessageBox::warning( NULL, "Basic Image Processing", "Input image is broken or not initialized. Returning.", QMessageBox::Ok, QMessageBox::NoButton );
     return;
   }
 
   // check if operation is done on 4D a image time step
   if(newImage->GetDimension() > 3)
   {
     mitk::ImageTimeSelector::Pointer timeSelector = mitk::ImageTimeSelector::New();
     timeSelector->SetInput(newImage);
     timeSelector->SetTimeNr( ((QmitkSliderNavigatorWidget*)m_Controls->sliceNavigatorTime)->GetPos() );
     timeSelector->Update();
     newImage = timeSelector->GetOutput();
   }
 
 
 
   // check if image or vector image
   ImageType::Pointer itkImage = ImageType::New();
   VectorImageType::Pointer itkVecImage = VectorImageType::New();
 
   int isVectorImage = newImage->GetPixelType().GetNumberOfComponents();
 
   if(isVectorImage > 1)
   {
     CastToItkImage( newImage, itkVecImage );
   }
   else
   {
     CastToItkImage( newImage, itkImage );
   }
 
   std::stringstream nameAddition("");
 
   int param1 = m_Controls->sbParam1->value();
   int param2 = m_Controls->sbParam2->value();
   double dparam1 = m_Controls->dsbParam1->value();
   double dparam2 = m_Controls->dsbParam2->value();
   double dparam3 = m_Controls->dsbParam3->value();
 
   try{
 
   switch (m_SelectedAction)
   {
 
   case GAUSSIAN:
     {
       GaussianFilterType::Pointer gaussianFilter = GaussianFilterType::New();
       gaussianFilter->SetInput( itkImage );
       gaussianFilter->SetVariance( param1 );
       gaussianFilter->UpdateLargestPossibleRegion();
       newImage = mitk::ImportItkImage(gaussianFilter->GetOutput())->Clone();
       nameAddition << "_Gaussian_var_" << param1;
       std::cout << "Gaussian filtering successful." << std::endl;
       break;
     }
 
   case MEDIAN:
     {
       MedianFilterType::Pointer medianFilter = MedianFilterType::New();
       MedianFilterType::InputSizeType size;
       size.Fill(param1);
       medianFilter->SetRadius( size );
       medianFilter->SetInput(itkImage);
       medianFilter->UpdateLargestPossibleRegion();
       newImage = mitk::ImportItkImage(medianFilter->GetOutput())->Clone();
       nameAddition << "_Median_radius_" << param1;
       std::cout << "Median Filtering successful." << std::endl;
       break;
     }
 
   case TOTALVARIATION:
     {
       if(isVectorImage > 1)
       {
         VectorTotalVariationFilterType::Pointer TVFilter
           = VectorTotalVariationFilterType::New();
         TVFilter->SetInput( itkVecImage.GetPointer() );
         TVFilter->SetNumberIterations(param1);
         TVFilter->SetLambda(double(param2)/1000.);
         TVFilter->UpdateLargestPossibleRegion();
 
         newImage = mitk::ImportItkImage(TVFilter->GetOutput())->Clone();
       }
       else
       {
         ImagePTypeToFloatPTypeCasterType::Pointer floatCaster = ImagePTypeToFloatPTypeCasterType::New();
         floatCaster->SetInput( itkImage );
         floatCaster->Update();
-        FloatImageType::Pointer fImage = floatCaster->GetOutput();
+        DoubleImageType::Pointer fImage = floatCaster->GetOutput();
 
         TotalVariationFilterType::Pointer TVFilter
           = TotalVariationFilterType::New();
         TVFilter->SetInput( fImage.GetPointer() );
         TVFilter->SetNumberIterations(param1);
         TVFilter->SetLambda(double(param2)/1000.);
         TVFilter->UpdateLargestPossibleRegion();
 
         newImage = mitk::ImportItkImage(TVFilter->GetOutput())->Clone();
       }
 
       nameAddition << "_TV_Iter_" << param1 << "_L_" << param2;
       std::cout << "Total Variation Filtering successful." << std::endl;
       break;
     }
 
   case DILATION:
     {
       BallType binaryBall;
       binaryBall.SetRadius( param1 );
       binaryBall.CreateStructuringElement();
 
       DilationFilterType::Pointer dilationFilter = DilationFilterType::New();
       dilationFilter->SetInput( itkImage );
       dilationFilter->SetKernel( binaryBall );
       dilationFilter->UpdateLargestPossibleRegion();
       newImage = mitk::ImportItkImage(dilationFilter->GetOutput())->Clone();
       nameAddition << "_Dilated_by_" << param1;
       std::cout << "Dilation successful." << std::endl;
       break;
     }
 
   case EROSION:
     {
       BallType binaryBall;
       binaryBall.SetRadius( param1 );
       binaryBall.CreateStructuringElement();
 
       ErosionFilterType::Pointer erosionFilter = ErosionFilterType::New();
       erosionFilter->SetInput( itkImage );
       erosionFilter->SetKernel( binaryBall );
       erosionFilter->UpdateLargestPossibleRegion();
       newImage = mitk::ImportItkImage(erosionFilter->GetOutput())->Clone();
       nameAddition << "_Eroded_by_" << param1;
       std::cout << "Erosion successful." << std::endl;
       break;
     }
 
   case OPENING:
     {
       BallType binaryBall;
       binaryBall.SetRadius( param1 );
       binaryBall.CreateStructuringElement();
 
       OpeningFilterType::Pointer openFilter = OpeningFilterType::New();
       openFilter->SetInput( itkImage );
       openFilter->SetKernel( binaryBall );
       openFilter->UpdateLargestPossibleRegion();
       newImage = mitk::ImportItkImage(openFilter->GetOutput())->Clone();
       nameAddition << "_Opened_by_" << param1;
       std::cout << "Opening successful." << std::endl;
       break;
     }
 
   case CLOSING:
     {
       BallType binaryBall;
       binaryBall.SetRadius( param1 );
       binaryBall.CreateStructuringElement();
 
       ClosingFilterType::Pointer closeFilter = ClosingFilterType::New();
       closeFilter->SetInput( itkImage );
       closeFilter->SetKernel( binaryBall );
       closeFilter->UpdateLargestPossibleRegion();
       newImage = mitk::ImportItkImage(closeFilter->GetOutput())->Clone();
       nameAddition << "_Closed_by_" << param1;
       std::cout << "Closing successful." << std::endl;
       break;
     }
 
   case GRADIENT:
     {
       GradientFilterType::Pointer gradientFilter = GradientFilterType::New();
       gradientFilter->SetInput( itkImage );
       gradientFilter->SetSigma( param1 );
       gradientFilter->UpdateLargestPossibleRegion();
       newImage = mitk::ImportItkImage(gradientFilter->GetOutput())->Clone();
       nameAddition << "_Gradient_sigma_" << param1;
       std::cout << "Gradient calculation successful." << std::endl;
       break;
     }
 
   case LAPLACIAN:
     {
       // the laplace filter requires a float type image as input, we need to cast the itkImage
       // to correct type
       ImagePTypeToFloatPTypeCasterType::Pointer caster = ImagePTypeToFloatPTypeCasterType::New();
       caster->SetInput( itkImage );
       caster->Update();
-      FloatImageType::Pointer fImage = caster->GetOutput();
+      DoubleImageType::Pointer fImage = caster->GetOutput();
 
       LaplacianFilterType::Pointer laplacianFilter = LaplacianFilterType::New();
       laplacianFilter->SetInput( fImage );
       laplacianFilter->UpdateLargestPossibleRegion();
       newImage = mitk::ImportItkImage(laplacianFilter->GetOutput())->Clone();
       nameAddition << "_Second_Derivative";
       std::cout << "Laplacian filtering successful." << std::endl;
       break;
     }
 
   case SOBEL:
     {
       // the sobel filter requires a float type image as input, we need to cast the itkImage
       // to correct type
       ImagePTypeToFloatPTypeCasterType::Pointer caster = ImagePTypeToFloatPTypeCasterType::New();
       caster->SetInput( itkImage );
       caster->Update();
-      FloatImageType::Pointer fImage = caster->GetOutput();
+      DoubleImageType::Pointer fImage = caster->GetOutput();
 
       SobelFilterType::Pointer sobelFilter = SobelFilterType::New();
       sobelFilter->SetInput( fImage );
       sobelFilter->UpdateLargestPossibleRegion();
       newImage = mitk::ImportItkImage(sobelFilter->GetOutput())->Clone();
       nameAddition << "_Sobel";
       std::cout << "Edge Detection successful." << std::endl;
       break;
     }
 
   case THRESHOLD:
     {
       ThresholdFilterType::Pointer thFilter = ThresholdFilterType::New();
       thFilter->SetLowerThreshold(param1 < param2 ? param1 : param2);
       thFilter->SetUpperThreshold(param2 > param1 ? param2 : param1);
       thFilter->SetInsideValue(1);
       thFilter->SetOutsideValue(0);
       thFilter->SetInput(itkImage);
       thFilter->UpdateLargestPossibleRegion();
       newImage = mitk::ImportItkImage(thFilter->GetOutput())->Clone();
       nameAddition << "_Threshold";
       std::cout << "Thresholding successful." << std::endl;
       break;
     }
 
   case INVERSION:
     {
       InversionFilterType::Pointer invFilter = InversionFilterType::New();
       mitk::ScalarType min = newImage->GetScalarValueMin();
       mitk::ScalarType max = newImage->GetScalarValueMax();
       invFilter->SetMaximum( max + min );
       invFilter->SetInput(itkImage);
       invFilter->UpdateLargestPossibleRegion();
       newImage = mitk::ImportItkImage(invFilter->GetOutput())->Clone();
       nameAddition << "_Inverted";
       std::cout << "Image inversion successful." << std::endl;
       break;
     }
 
   case DOWNSAMPLING:
     {
       ResampleImageFilterType::Pointer downsampler = ResampleImageFilterType::New();
       downsampler->SetInput( itkImage );
 
       NearestInterpolatorType::Pointer interpolator = NearestInterpolatorType::New();
       downsampler->SetInterpolator( interpolator );
 
       downsampler->SetDefaultPixelValue( 0 );
 
       ResampleImageFilterType::SpacingType spacing = itkImage->GetSpacing();
       spacing *= (double) param1;
       downsampler->SetOutputSpacing( spacing );
 
       downsampler->SetOutputOrigin( itkImage->GetOrigin() );
       downsampler->SetOutputDirection( itkImage->GetDirection() );
 
       ResampleImageFilterType::SizeType size = itkImage->GetLargestPossibleRegion().GetSize();
       for ( int i = 0; i < 3; ++i )
       {
         size[i] /= param1;
       }
       downsampler->SetSize( size );
       downsampler->UpdateLargestPossibleRegion();
 
       newImage = mitk::ImportItkImage(downsampler->GetOutput())->Clone();
       nameAddition << "_Downsampled_by_" << param1;
       std::cout << "Downsampling successful." << std::endl;
       break;
     }
 
   case FLIPPING:
     {
       FlipImageFilterType::Pointer flipper = FlipImageFilterType::New();
       flipper->SetInput( itkImage );
       itk::FixedArray<bool, 3> flipAxes;
       for(int i=0; i<3; ++i)
       {
         if(i == param1)
         {
           flipAxes[i] = true;
         }
         else
         {
           flipAxes[i] = false;
         }
       }
       flipper->SetFlipAxes(flipAxes);
       flipper->UpdateLargestPossibleRegion();
       newImage = mitk::ImportItkImage(flipper->GetOutput())->Clone();
       std::cout << "Image flipping successful." << std::endl;
       break;
     }
 
   case RESAMPLING:
     {
       std::string selectedInterpolator;
       ResampleImageFilterType::Pointer resampler = ResampleImageFilterType::New();
       switch (m_SelectedInterpolation)
       {
       case LINEAR:
         {
           LinearInterpolatorType::Pointer interpolator = LinearInterpolatorType::New();
           resampler->SetInterpolator(interpolator);
           selectedInterpolator = "Linear";
           break;
         }
       case NEAREST:
         {
           NearestInterpolatorType::Pointer interpolator = NearestInterpolatorType::New();
           resampler->SetInterpolator(interpolator);
           selectedInterpolator = "Nearest";
           break;
         }
       default:
         {
           LinearInterpolatorType::Pointer interpolator = LinearInterpolatorType::New();
           resampler->SetInterpolator(interpolator);
           selectedInterpolator = "Linear";
           break;
         }
       }
       resampler->SetInput( itkImage );
       resampler->SetOutputOrigin( itkImage->GetOrigin() );
 
       ImageType::SizeType input_size = itkImage->GetLargestPossibleRegion().GetSize();
       ImageType::SpacingType input_spacing = itkImage->GetSpacing();
 
       ImageType::SizeType output_size;
       ImageType::SpacingType output_spacing;
 
       output_size[0] = input_size[0] * (input_spacing[0] / dparam1);
       output_size[1] = input_size[1] * (input_spacing[1] / dparam2);
       output_size[2] = input_size[2] * (input_spacing[2] / dparam3);
       output_spacing [0] = dparam1;
       output_spacing [1] = dparam2;
       output_spacing [2] = dparam3;
 
       resampler->SetSize( output_size );
       resampler->SetOutputSpacing( output_spacing );
       resampler->SetOutputDirection( itkImage->GetDirection() );
 
       resampler->UpdateLargestPossibleRegion();
 
       ImageType::Pointer resampledImage = resampler->GetOutput();
 
       newImage = mitk::ImportItkImage( resampledImage )->Clone();
       nameAddition << "_Resampled_" << selectedInterpolator;
       std::cout << "Resampling successful." << std::endl;
       break;
     }
 
 
   case RESCALE:
     {
-      FloatImageType::Pointer floatImage = FloatImageType::New();
+      DoubleImageType::Pointer floatImage = DoubleImageType::New();
       CastToItkImage( newImage, floatImage );
-      itk::RescaleIntensityImageFilter<FloatImageType,FloatImageType>::Pointer filter = itk::RescaleIntensityImageFilter<FloatImageType,FloatImageType>::New();
+      itk::RescaleIntensityImageFilter<DoubleImageType,DoubleImageType>::Pointer filter = itk::RescaleIntensityImageFilter<DoubleImageType,DoubleImageType>::New();
       filter->SetInput(0, floatImage);
       filter->SetOutputMinimum(dparam1);
       filter->SetOutputMaximum(dparam2);
       filter->Update();
       floatImage = filter->GetOutput();
 
       newImage = mitk::Image::New();
       newImage->InitializeByItk(floatImage.GetPointer());
       newImage->SetVolume(floatImage->GetBufferPointer());
       nameAddition << "_Rescaled";
       std::cout << "Rescaling successful." << std::endl;
 
       break;
     }
+  case RESCALE2:
+  {
+      DoubleImageType::Pointer floatImage = DoubleImageType::New();
+      CastToItkImage( newImage, floatImage );
+      itk::ShiftScaleImageFilter<DoubleImageType,DoubleImageType>::Pointer filter = itk::ShiftScaleImageFilter<DoubleImageType,DoubleImageType>::New();
+      filter->SetInput(0, floatImage);
+      filter->SetScale(dparam1);
+
+      filter->Update();
+      floatImage = filter->GetOutput();
+
+      newImage = mitk::Image::New();
+      newImage->InitializeByItk(floatImage.GetPointer());
+      newImage->SetVolume(floatImage->GetBufferPointer());
+      nameAddition << "_Rescaled";
+      std::cout << "Rescaling successful." << std::endl;
+      break;
+  }
 
   default:
     this->BusyCursorOff();
     return;
   }
   }
   catch (...)
   {
     this->BusyCursorOff();
     QMessageBox::warning(NULL, "Warning", "Problem when applying filter operation. Check your input...");
     return;
   }
 
   newImage->DisconnectPipeline();
 
   // adjust level/window to new image
   mitk::LevelWindow levelwindow;
   levelwindow.SetAuto( newImage );
   mitk::LevelWindowProperty::Pointer levWinProp = mitk::LevelWindowProperty::New();
   levWinProp->SetLevelWindow( levelwindow );
 
   // compose new image name
   std::string name = m_SelectedImageNode->GetNode()->GetName();
   if (name.find(".pic.gz") == name.size() -7 )
   {
     name = name.substr(0,name.size() -7);
   }
   name.append( nameAddition.str() );
 
   // create final result MITK data storage node
   mitk::DataNode::Pointer result = mitk::DataNode::New();
   result->SetProperty( "levelwindow", levWinProp );
   result->SetProperty( "name", mitk::StringProperty::New( name.c_str() ) );
   result->SetData( newImage );
 
   // for vector images, a different mapper is needed
   if(isVectorImage > 1)
   {
     mitk::VectorImageMapper2D::Pointer mapper =
       mitk::VectorImageMapper2D::New();
     result->SetMapper(1,mapper);
   }
 
   // reset GUI to ease further processing
 //  this->ResetOneImageOpPanel();
 
   // add new image to data storage and set as active to ease further processing
   GetDefaultDataStorage()->Add( result, m_SelectedImageNode->GetNode() );
   if ( m_Controls->cbHideOrig->isChecked() == true )
     m_SelectedImageNode->GetNode()->SetProperty( "visible", mitk::BoolProperty::New(false) );
   // TODO!! m_Controls->m_ImageSelector1->SetSelectedNode(result);
 
   // show the results
   mitk::RenderingManager::GetInstance()->RequestUpdateAll();
   this->BusyCursorOff();
 }
 
 void QmitkBasicImageProcessing::SelectAction2(int operation)
 {
   // check which operation the user has selected and set parameters and GUI accordingly
   switch (operation)
   {
   case 2:
     m_SelectedOperation = ADD;
     break;
   case 3:
     m_SelectedOperation = SUBTRACT;
     break;
   case 4:
     m_SelectedOperation = MULTIPLY;
     break;
   case 5:
     m_SelectedOperation = DIVIDE;
     break;
   case 6:
     m_SelectedOperation = RESAMPLE_TO;
     break;
   case 8:
     m_SelectedOperation = AND;
     break;
   case 9:
     m_SelectedOperation = OR;
     break;
   case 10:
     m_SelectedOperation = XOR;
     break;
   default:
 //    this->ResetTwoImageOpPanel();
     return;
   }
   m_Controls->tlImage2->setEnabled(true);
   m_Controls->m_ImageSelector2->setEnabled(true);
   m_Controls->btnDoIt2->setEnabled(true);
 }
 
 void QmitkBasicImageProcessing::StartButton2Clicked()
 {
   mitk::Image::Pointer newImage1 = dynamic_cast<mitk::Image*>
     (m_SelectedImageNode->GetNode()->GetData());
   mitk::Image::Pointer newImage2 = dynamic_cast<mitk::Image*>
     (m_Controls->m_ImageSelector2->GetSelectedNode()->GetData());
 
   // check if images are valid
   if( (!newImage1) || (!newImage2) || (newImage1->IsInitialized() == false) || (newImage2->IsInitialized() == false) )
   {
     itkGenericExceptionMacro(<< "At least one of the input images are broken or not initialized. Returning");
     return;
   }
 
   this->BusyCursorOn();
 //  this->ResetTwoImageOpPanel();
 
   // check if 4D image and use filter on correct time step
   int time = ((QmitkSliderNavigatorWidget*)m_Controls->sliceNavigatorTime)->GetPos();
   if(newImage1->GetDimension() > 3)
   {
     mitk::ImageTimeSelector::Pointer timeSelector = mitk::ImageTimeSelector::New();
 
     timeSelector->SetInput(newImage1);
     timeSelector->SetTimeNr( time );
     timeSelector->UpdateLargestPossibleRegion();
     newImage1 = timeSelector->GetOutput();
     newImage1->DisconnectPipeline();
 
     timeSelector->SetInput(newImage2);
     timeSelector->SetTimeNr( time );
     timeSelector->UpdateLargestPossibleRegion();
     newImage2 = timeSelector->GetOutput();
     newImage2->DisconnectPipeline();
   }
 
   // reset GUI for better usability
 //  this->ResetTwoImageOpPanel();
 
   ImageType::Pointer itkImage1 = ImageType::New();
   ImageType::Pointer itkImage2 = ImageType::New();
 
   CastToItkImage( newImage1, itkImage1 );
   CastToItkImage( newImage2, itkImage2 );
 
   // Remove temp image
-  newImage2 = NULL;
+//  newImage2 = NULL;
 
   std::string nameAddition = "";
 
   try
   {
   switch (m_SelectedOperation)
   {
   case ADD:
     {
       AddFilterType::Pointer addFilter = AddFilterType::New();
       addFilter->SetInput1( itkImage1 );
       addFilter->SetInput2( itkImage2 );
       addFilter->UpdateLargestPossibleRegion();
       newImage1 = mitk::ImportItkImage(addFilter->GetOutput())->Clone();
       nameAddition = "_Added";
     }
     break;
 
   case SUBTRACT:
     {
       SubtractFilterType::Pointer subFilter = SubtractFilterType::New();
       subFilter->SetInput1( itkImage1 );
       subFilter->SetInput2( itkImage2 );
       subFilter->UpdateLargestPossibleRegion();
       newImage1 = mitk::ImportItkImage(subFilter->GetOutput())->Clone();
       nameAddition = "_Subtracted";
     }
     break;
 
   case MULTIPLY:
     {
       MultiplyFilterType::Pointer multFilter = MultiplyFilterType::New();
       multFilter->SetInput1( itkImage1 );
       multFilter->SetInput2( itkImage2 );
       multFilter->UpdateLargestPossibleRegion();
       newImage1 = mitk::ImportItkImage(multFilter->GetOutput())->Clone();
       nameAddition = "_Multiplied";
     }
     break;
 
   case DIVIDE:
     {
       DivideFilterType::Pointer divFilter = DivideFilterType::New();
       divFilter->SetInput1( itkImage1 );
       divFilter->SetInput2( itkImage2 );
       divFilter->UpdateLargestPossibleRegion();
-      newImage1 = mitk::ImportItkImage<FloatImageType>(divFilter->GetOutput())->Clone();
+      newImage1 = mitk::ImportItkImage<DoubleImageType>(divFilter->GetOutput())->Clone();
       nameAddition = "_Divided";
     }
     break;
 
   case AND:
     {
       AndImageFilterType::Pointer andFilter = AndImageFilterType::New();
       andFilter->SetInput1( itkImage1 );
       andFilter->SetInput2( itkImage2 );
       andFilter->UpdateLargestPossibleRegion();
       newImage1 = mitk::ImportItkImage(andFilter->GetOutput())->Clone();
       nameAddition = "_AND";
       break;
     }
 
   case OR:
     {
       OrImageFilterType::Pointer orFilter = OrImageFilterType::New();
       orFilter->SetInput1( itkImage1 );
       orFilter->SetInput2( itkImage2 );
       orFilter->UpdateLargestPossibleRegion();
       newImage1 = mitk::ImportItkImage(orFilter->GetOutput())->Clone();
       nameAddition = "_OR";
       break;
     }
 
   case XOR:
     {
       XorImageFilterType::Pointer xorFilter = XorImageFilterType::New();
       xorFilter->SetInput1( itkImage1 );
       xorFilter->SetInput2( itkImage2 );
       xorFilter->UpdateLargestPossibleRegion();
       newImage1 = mitk::ImportItkImage(xorFilter->GetOutput())->Clone();
       nameAddition = "_XOR";
       break;
     }
 
   case RESAMPLE_TO:
     {
 
-      itk::NearestNeighborInterpolateImageFunction<ImageType>::Pointer nn_interpolator
-        = itk::NearestNeighborInterpolateImageFunction<ImageType>::New();
+      itk::LinearInterpolateImageFunction<DoubleImageType>::Pointer nn_interpolator
+        = itk::LinearInterpolateImageFunction<DoubleImageType>::New();
+
+      DoubleImageType::Pointer itkImage1 = DoubleImageType::New();
+      DoubleImageType::Pointer itkImage2 = DoubleImageType::New();
+
+      CastToItkImage( newImage1, itkImage1 );
+      CastToItkImage( newImage2, itkImage2 );
 
-      ResampleImageFilterType2::Pointer resampleFilter = ResampleImageFilterType2::New();
+      itk::ResampleImageFilter< DoubleImageType, DoubleImageType >::Pointer resampleFilter = itk::ResampleImageFilter< DoubleImageType, DoubleImageType >::New();
       resampleFilter->SetInput( itkImage1 );
       resampleFilter->SetReferenceImage( itkImage2 );
       resampleFilter->SetUseReferenceImage( true );
       resampleFilter->SetInterpolator( nn_interpolator );
       resampleFilter->SetDefaultPixelValue( 0 );
 
       try
       {
         resampleFilter->UpdateLargestPossibleRegion();
       }
       catch( const itk::ExceptionObject &e)
       {
         MITK_WARN << "Updating resampling filter failed. ";
         MITK_WARN << "REASON: " << e.what();
       }
 
-      ImageType::Pointer resampledImage = resampleFilter->GetOutput();
+      DoubleImageType::Pointer resampledImage = resampleFilter->GetOutput();
 
       newImage1 = mitk::ImportItkImage( resampledImage )->Clone();
       nameAddition = "_Resampled";
       break;
     }
 
   default:
     std::cout << "Something went wrong..." << std::endl;
     this->BusyCursorOff();
     return;
   }
   }
   catch (const itk::ExceptionObject& e )
   {
     this->BusyCursorOff();
     QMessageBox::warning(NULL, "ITK Exception", e.what() );
     QMessageBox::warning(NULL, "Warning", "Problem when applying arithmetic operation to two images. Check dimensions of input images.");
     return;
   }
 
   // disconnect pipeline; images will not be reused
   newImage1->DisconnectPipeline();
   itkImage1 = NULL;
   itkImage2 = NULL;
 
   // adjust level/window to new image and compose new image name
   mitk::LevelWindow levelwindow;
   levelwindow.SetAuto( newImage1 );
   mitk::LevelWindowProperty::Pointer levWinProp = mitk::LevelWindowProperty::New();
   levWinProp->SetLevelWindow( levelwindow );
   std::string name = m_SelectedImageNode->GetNode()->GetName();
   if (name.find(".pic.gz") == name.size() -7 )
   {
     name = name.substr(0,name.size() -7);
   }
 
   // create final result MITK data storage node
   mitk::DataNode::Pointer result = mitk::DataNode::New();
   result->SetProperty( "levelwindow", levWinProp );
   result->SetProperty( "name", mitk::StringProperty::New( (name + nameAddition ).c_str() ));
   result->SetData( newImage1 );
   GetDefaultDataStorage()->Add( result, m_SelectedImageNode->GetNode() );
 
   // show only the newly created image
   m_SelectedImageNode->GetNode()->SetProperty( "visible", mitk::BoolProperty::New(false) );
   m_Controls->m_ImageSelector2->GetSelectedNode()->SetProperty( "visible", mitk::BoolProperty::New(false) );
 
   // show the newly created image
   mitk::RenderingManager::GetInstance()->RequestUpdateAll();
   this->BusyCursorOff();
 }
 
 void QmitkBasicImageProcessing::SelectInterpolator(int interpolator)
 {
   switch (interpolator)
   {
   case 0:
     {
       m_SelectedInterpolation = LINEAR;
       break;
     }
   case 1:
     {
       m_SelectedInterpolation = NEAREST;
       break;
     }
   }
 }
diff --git a/Plugins/org.mitk.gui.qt.basicimageprocessing/src/internal/QmitkBasicImageProcessingView.h b/Plugins/org.mitk.gui.qt.basicimageprocessing/src/internal/QmitkBasicImageProcessingView.h
index 0e11c58395..3d0d7a1d51 100644
--- a/Plugins/org.mitk.gui.qt.basicimageprocessing/src/internal/QmitkBasicImageProcessingView.h
+++ b/Plugins/org.mitk.gui.qt.basicimageprocessing/src/internal/QmitkBasicImageProcessingView.h
@@ -1,185 +1,186 @@
 /*===================================================================
 
 The Medical Imaging Interaction Toolkit (MITK)
 
 Copyright (c) German Cancer Research Center,
 Division of Medical and Biological Informatics.
 All rights reserved.
 
 This software is distributed WITHOUT ANY WARRANTY; without
 even the implied warranty of MERCHANTABILITY or FITNESS FOR
 A PARTICULAR PURPOSE.
 
 See LICENSE.txt or http://www.mitk.org for details.
 
 ===================================================================*/
 
 #if !defined(QmitkBasicImageProcessingView_H__INCLUDED)
 #define QmitkBasicImageProcessingView_H__INCLUDED
 
 #include "QmitkFunctionality.h"
 #include <org_mitk_gui_qt_basicimageprocessing_Export.h>
 #include "ui_QmitkBasicImageProcessingViewControls.h"
 
 #include "QmitkStepperAdapter.h"
 
 #include <mitkDataStorageSelection.h>
 
 /*!
 \brief This module allows to use some basic image processing filters for preprocessing, image enhancement and testing purposes
 
 Several basic ITK image processing filters, like denoising, morphological and edge detection
 are encapsulated in this module and can be selected via a list and an intuitive parameter input.
 The selected filter will be applied on the image, and a new image showing the output is displayed
 as result.
 Also, some image arithmetic operations are available.
 
 Images can be 3D or 4D.
 In the 4D case, the filters work on the 3D image selected via the
 time slider. The result is also a 3D image.
 
 \sa QmitkFunctionality, QObject
 
 \class QmitkBasicImageProcessing
 \author Tobias Schwarz
 \version 1.0 (3M3)
 \date 2009-05-10
 \ingroup Bundles
 */
 
 class BASICIMAGEPROCESSING_EXPORT QmitkBasicImageProcessing : public QmitkFunctionality
 {
   Q_OBJECT
 
 public:
 
   /*!
   \brief default constructor
   */
   QmitkBasicImageProcessing();
 
   /*!
   \brief default destructor
   */
   virtual ~QmitkBasicImageProcessing();
 
   /*!
   \brief method for creating the widget containing the application controls, like sliders, buttons etc.
   */
   virtual void CreateQtPartControl(QWidget *parent);
 
   /*!
   \brief method for creating the connections of main and control widget
   */
   virtual void CreateConnections();
 
   virtual void Activated();
 
   /*!
   \brief Invoked when the DataManager selection changed
   */
   virtual void OnSelectionChanged(std::vector<mitk::DataNode*> nodes);
 
 
   protected slots:
 
     /*
     * When an action is selected in the "one image ops" list box
     */
     void SelectAction(int action);
 
     /*
     * When an action is selected in the "two image ops" list box
     */
     void SelectAction2(int operation);
 
     /*
     * The "Execute" button in the "one image ops" box was triggered
     */
     void StartButtonClicked();
 
     /*
     * The "Execute" button in the "two image ops" box was triggered
     */
     void StartButton2Clicked();
 
     /*
     *  Switch between the one and the two image operations GUI
     */
     void ChangeGUI();
 
     void SelectInterpolator(int interpolator);
 
 private:
 
   /*
   * After a one image operation, reset the "one image ops" panel
   */
   void ResetOneImageOpPanel();
 
   /*
   * Helper method to reset the parameter set panel
   */
   void ResetParameterPanel();
 
   /*
   * After a two image operation, reset the "two image ops" panel
   */
   void ResetTwoImageOpPanel();
 
   /*!
   * controls containing sliders for scrolling through the slices
   */
   Ui::QmitkBasicImageProcessingViewControls *m_Controls;
 
   //mitk::DataNode*       m_SelectedImageNode;
   mitk::DataStorageSelection::Pointer m_SelectedImageNode;
   QmitkStepperAdapter*      m_TimeStepperAdapter;
 
   enum ActionType {
     NOACTIONSELECTED,
     CATEGORY_DENOISING,
     GAUSSIAN,
     MEDIAN,
     TOTALVARIATION,
     CATEGORY_MORPHOLOGICAL,
     DILATION,
     EROSION,
     OPENING,
     CLOSING,
     CATEGORY_EDGE_DETECTION,
     GRADIENT,
     LAPLACIAN,
     SOBEL,
     CATEGORY_MISC,
     THRESHOLD,
     INVERSION,
     DOWNSAMPLING,
     FLIPPING,
     RESAMPLING,
-    RESCALE
+    RESCALE,
+    RESCALE2
   } m_SelectedAction;
 
   enum OperationType{
     TWOIMAGESNOACTIONSELECTED,
     CATEGORY_ARITHMETIC,
     ADD,
     SUBTRACT,
     MULTIPLY,
     DIVIDE,
     RESAMPLE_TO,
     CATEGORY_BOOLEAN,
     AND,
     OR,
     XOR
   } m_SelectedOperation;
 
   enum InterpolationType{
     LINEAR,
     NEAREST
   } m_SelectedInterpolation;
 };
 
 #endif // !defined(QmitkBasicImageProcessing_H__INCLUDED)
 
 
diff --git a/Plugins/org.mitk.gui.qt.basicimageprocessing/src/internal/QmitkBasicImageProcessingViewControls.ui b/Plugins/org.mitk.gui.qt.basicimageprocessing/src/internal/QmitkBasicImageProcessingViewControls.ui
index 0febdf1c5a..179daf05a9 100644
--- a/Plugins/org.mitk.gui.qt.basicimageprocessing/src/internal/QmitkBasicImageProcessingViewControls.ui
+++ b/Plugins/org.mitk.gui.qt.basicimageprocessing/src/internal/QmitkBasicImageProcessingViewControls.ui
@@ -1,443 +1,473 @@
 <?xml version="1.0" encoding="UTF-8"?>
 <ui version="4.0">
  <class>QmitkBasicImageProcessingViewControls</class>
  <widget class="QWidget" name="QmitkBasicImageProcessingViewControls">
   <property name="geometry">
    <rect>
     <x>0</x>
     <y>0</y>
-    <width>349</width>
+    <width>448</width>
     <height>980</height>
    </rect>
   </property>
   <property name="windowTitle">
    <string>Form</string>
   </property>
   <layout class="QGridLayout" name="gridLayout_4">
    <item row="0" column="0">
     <widget class="QGroupBox" name="groupBox">
      <property name="title">
       <string/>
      </property>
      <property name="flat">
       <bool>true</bool>
      </property>
      <layout class="QGridLayout" name="gridLayout_3">
       <property name="leftMargin">
        <number>0</number>
       </property>
       <property name="topMargin">
        <number>6</number>
       </property>
       <property name="rightMargin">
        <number>0</number>
       </property>
       <property name="bottomMargin">
        <number>6</number>
       </property>
       <item row="0" column="0">
        <widget class="QRadioButton" name="rBOneImOp">
         <property name="text">
          <string>Filters
 (One Image)</string>
         </property>
         <property name="checked">
          <bool>true</bool>
         </property>
        </widget>
       </item>
       <item row="0" column="1">
        <widget class="QRadioButton" name="rBTwoImOp">
         <property name="text">
          <string>Arithmetic
 (Two Images)</string>
         </property>
        </widget>
       </item>
       <item row="1" column="0" colspan="2">
        <widget class="QLineEdit" name="leImage1">
         <property name="text">
          <string>Select an Image in Data Manager</string>
         </property>
         <property name="readOnly">
          <bool>true</bool>
         </property>
        </widget>
       </item>
       <item row="2" column="0">
        <widget class="QLabel" name="tlTime">
         <property name="enabled">
          <bool>false</bool>
         </property>
         <property name="toolTip">
          <string>Output image will be 3D</string>
         </property>
         <property name="text">
          <string>Choose time step if 4D
 (Slider for both images)</string>
         </property>
         <property name="wordWrap">
          <bool>false</bool>
         </property>
        </widget>
       </item>
       <item row="2" column="1">
        <widget class="QmitkSliderNavigatorWidget" name="sliceNavigatorTime" native="true">
         <property name="enabled">
          <bool>false</bool>
         </property>
         <property name="toolTip">
          <string>Output image will be 3D</string>
         </property>
        </widget>
       </item>
      </layout>
     </widget>
    </item>
    <item row="2" column="0">
     <widget class="QGroupBox" name="gbTwoImageOps">
      <property name="enabled">
       <bool>true</bool>
      </property>
      <property name="title">
       <string/>
      </property>
      <property name="flat">
       <bool>true</bool>
      </property>
      <property name="checkable">
       <bool>false</bool>
      </property>
      <property name="checked">
       <bool>false</bool>
      </property>
      <layout class="QGridLayout" name="gridLayout_2">
       <property name="leftMargin">
        <number>0</number>
       </property>
       <property name="topMargin">
        <number>6</number>
       </property>
       <property name="rightMargin">
        <number>0</number>
       </property>
       <property name="bottomMargin">
        <number>0</number>
       </property>
       <item row="2" column="0" colspan="2">
        <widget class="QLabel" name="tlImage2">
         <property name="enabled">
          <bool>false</bool>
         </property>
         <property name="text">
          <string>Select second image:</string>
         </property>
         <property name="wordWrap">
          <bool>false</bool>
         </property>
         <property name="buddy">
          <cstring>m_ImageSelector2</cstring>
         </property>
        </widget>
       </item>
       <item row="3" column="0" colspan="3">
        <widget class="QmitkDataStorageComboBox" name="m_ImageSelector2">
         <property name="enabled">
          <bool>false</bool>
         </property>
        </widget>
       </item>
       <item row="6" column="0" colspan="3">
        <widget class="QPushButton" name="btnDoIt2">
         <property name="enabled">
          <bool>false</bool>
         </property>
         <property name="text">
          <string>E&amp;xecute</string>
         </property>
        </widget>
       </item>
       <item row="0" column="0">
        <widget class="QLabel" name="tlWhat2">
         <property name="enabled">
          <bool>false</bool>
         </property>
         <property name="text">
          <string>Select an operation:</string>
         </property>
         <property name="wordWrap">
          <bool>false</bool>
         </property>
         <property name="buddy">
          <cstring>cbWhat2</cstring>
         </property>
        </widget>
       </item>
       <item row="1" column="0" colspan="3">
        <widget class="QComboBox" name="cbWhat2">
         <property name="enabled">
          <bool>false</bool>
         </property>
        </widget>
       </item>
      </layout>
     </widget>
    </item>
    <item row="3" column="0">
     <spacer name="verticalSpacer">
      <property name="orientation">
       <enum>Qt::Vertical</enum>
      </property>
      <property name="sizeHint" stdset="0">
       <size>
        <width>254</width>
        <height>403</height>
       </size>
      </property>
     </spacer>
    </item>
    <item row="1" column="0">
     <widget class="QGroupBox" name="gbOneImageOps">
      <property name="title">
       <string/>
      </property>
      <property name="flat">
       <bool>true</bool>
      </property>
      <layout class="QGridLayout" name="gridLayout">
       <property name="leftMargin">
        <number>0</number>
       </property>
       <property name="topMargin">
        <number>6</number>
       </property>
       <property name="rightMargin">
        <number>0</number>
       </property>
       <property name="bottomMargin">
        <number>0</number>
       </property>
       <item row="0" column="0" colspan="3">
        <widget class="QLabel" name="tlWhat1">
         <property name="enabled">
          <bool>false</bool>
         </property>
         <property name="text">
          <string>Select an operation:</string>
         </property>
         <property name="wordWrap">
          <bool>false</bool>
         </property>
         <property name="buddy">
          <cstring>cbWhat1</cstring>
         </property>
        </widget>
       </item>
       <item row="1" column="0" colspan="3">
        <widget class="QComboBox" name="cbWhat1">
         <property name="enabled">
          <bool>false</bool>
         </property>
        </widget>
       </item>
       <item row="2" column="0" colspan="3">
        <widget class="QLabel" name="tlParam">
         <property name="enabled">
          <bool>false</bool>
         </property>
         <property name="text">
          <string>... and parameters:</string>
         </property>
         <property name="wordWrap">
          <bool>false</bool>
         </property>
        </widget>
       </item>
       <item row="3" column="0">
        <widget class="QLabel" name="tlParam1">
         <property name="enabled">
          <bool>false</bool>
         </property>
         <property name="text">
          <string>Parameter 1:</string>
         </property>
         <property name="wordWrap">
          <bool>false</bool>
         </property>
         <property name="buddy">
          <cstring>sbParam1</cstring>
         </property>
        </widget>
       </item>
       <item row="4" column="0">
        <widget class="QLabel" name="tlParam2">
         <property name="enabled">
          <bool>false</bool>
         </property>
         <property name="text">
          <string>Parameter 2:</string>
         </property>
         <property name="wordWrap">
          <bool>false</bool>
         </property>
         <property name="buddy">
          <cstring>sbParam2</cstring>
         </property>
        </widget>
       </item>
       <item row="8" column="0" colspan="3">
        <widget class="QPushButton" name="btnDoIt">
         <property name="enabled">
          <bool>false</bool>
         </property>
         <property name="text">
          <string>&amp;Execute</string>
         </property>
        </widget>
       </item>
       <item row="7" column="0">
        <widget class="QCheckBox" name="cbHideOrig">
         <property name="enabled">
          <bool>false</bool>
         </property>
         <property name="text">
          <string>Hide Original Image</string>
         </property>
         <property name="checked">
          <bool>true</bool>
         </property>
        </widget>
       </item>
       <item row="5" column="0">
        <widget class="QLabel" name="tlParam3">
         <property name="enabled">
          <bool>false</bool>
         </property>
         <property name="text">
          <string>Parameter 3:</string>
         </property>
        </widget>
       </item>
       <item row="6" column="0">
        <widget class="QLabel" name="tlParam4">
         <property name="enabled">
          <bool>false</bool>
         </property>
         <property name="text">
          <string>Parameter 4:</string>
         </property>
        </widget>
       </item>
       <item row="6" column="2">
        <widget class="QComboBox" name="cbParam4">
         <property name="enabled">
          <bool>false</bool>
         </property>
         <property name="sizePolicy">
          <sizepolicy hsizetype="Expanding" vsizetype="Fixed">
           <horstretch>0</horstretch>
           <verstretch>0</verstretch>
          </sizepolicy>
         </property>
        </widget>
       </item>
       <item row="5" column="2">
        <widget class="QDoubleSpinBox" name="dsbParam3">
         <property name="enabled">
          <bool>false</bool>
         </property>
         <property name="sizePolicy">
          <sizepolicy hsizetype="Expanding" vsizetype="Fixed">
           <horstretch>0</horstretch>
           <verstretch>0</verstretch>
          </sizepolicy>
         </property>
         <property name="layoutDirection">
          <enum>Qt::LeftToRight</enum>
         </property>
         <property name="alignment">
          <set>Qt::AlignLeading|Qt::AlignLeft|Qt::AlignVCenter</set>
         </property>
+        <property name="decimals">
+         <number>4</number>
+        </property>
+        <property name="minimum">
+         <double>-999999999.000000000000000</double>
+        </property>
+        <property name="maximum">
+         <double>999999999.000000000000000</double>
+        </property>
        </widget>
       </item>
       <item row="4" column="2">
        <widget class="QDoubleSpinBox" name="dsbParam2">
         <property name="enabled">
          <bool>false</bool>
         </property>
         <property name="sizePolicy">
          <sizepolicy hsizetype="Expanding" vsizetype="Fixed">
           <horstretch>0</horstretch>
           <verstretch>0</verstretch>
          </sizepolicy>
         </property>
+        <property name="decimals">
+         <number>4</number>
+        </property>
+        <property name="minimum">
+         <double>-999999999.000000000000000</double>
+        </property>
         <property name="maximum">
          <double>999999999.000000000000000</double>
         </property>
        </widget>
       </item>
       <item row="3" column="2">
        <widget class="QDoubleSpinBox" name="dsbParam1">
         <property name="enabled">
          <bool>false</bool>
         </property>
         <property name="sizePolicy">
          <sizepolicy hsizetype="Expanding" vsizetype="Fixed">
           <horstretch>0</horstretch>
           <verstretch>0</verstretch>
          </sizepolicy>
         </property>
         <property name="decimals">
-         <number>2</number>
+         <number>4</number>
+        </property>
+        <property name="minimum">
+         <double>-999999999.000000000000000</double>
         </property>
         <property name="maximum">
          <double>999999999.000000000000000</double>
         </property>
        </widget>
       </item>
       <item row="3" column="1">
        <widget class="QSpinBox" name="sbParam1">
         <property name="enabled">
          <bool>false</bool>
         </property>
         <property name="sizePolicy">
          <sizepolicy hsizetype="Expanding" vsizetype="Fixed">
           <horstretch>0</horstretch>
           <verstretch>0</verstretch>
          </sizepolicy>
         </property>
+        <property name="minimum">
+         <number>-999999999</number>
+        </property>
+        <property name="maximum">
+         <number>999999999</number>
+        </property>
        </widget>
       </item>
       <item row="4" column="1">
        <widget class="QSpinBox" name="sbParam2">
         <property name="enabled">
          <bool>false</bool>
         </property>
         <property name="sizePolicy">
          <sizepolicy hsizetype="Expanding" vsizetype="Fixed">
           <horstretch>0</horstretch>
           <verstretch>0</verstretch>
          </sizepolicy>
         </property>
+        <property name="minimum">
+         <number>-999999999</number>
+        </property>
+        <property name="maximum">
+         <number>999999999</number>
+        </property>
        </widget>
       </item>
      </layout>
     </widget>
    </item>
   </layout>
  </widget>
  <customwidgets>
   <customwidget>
    <class>QmitkDataStorageComboBox</class>
    <extends>QComboBox</extends>
    <header location="global">QmitkDataStorageComboBox.h</header>
   </customwidget>
   <customwidget>
    <class>QmitkSliderNavigatorWidget</class>
    <extends>QWidget</extends>
    <header location="global">QmitkSliderNavigatorWidget.h</header>
   </customwidget>
  </customwidgets>
  <resources/>
  <connections/>
 </ui>
diff --git a/Plugins/org.mitk.gui.qt.diffusionimaging/src/internal/QmitkControlVisualizationPropertiesView.cpp b/Plugins/org.mitk.gui.qt.diffusionimaging/src/internal/QmitkControlVisualizationPropertiesView.cpp
index eb69396981..d6aba3b5f3 100644
--- a/Plugins/org.mitk.gui.qt.diffusionimaging/src/internal/QmitkControlVisualizationPropertiesView.cpp
+++ b/Plugins/org.mitk.gui.qt.diffusionimaging/src/internal/QmitkControlVisualizationPropertiesView.cpp
@@ -1,1030 +1,1029 @@
 /*===================================================================
 
 The Medical Imaging Interaction Toolkit (MITK)
 
 Copyright (c) German Cancer Research Center,
 Division of Medical and Biological Informatics.
 All rights reserved.
 
 This software is distributed WITHOUT ANY WARRANTY; without
 even the implied warranty of MERCHANTABILITY or FITNESS FOR
 A PARTICULAR PURPOSE.
 
 See LICENSE.txt or http://www.mitk.org for details.
 
 ===================================================================*/
 
 #include "QmitkControlVisualizationPropertiesView.h"
 
 #include "mitkNodePredicateDataType.h"
 #include "mitkDataNodeObject.h"
 #include "mitkOdfNormalizationMethodProperty.h"
 #include "mitkOdfScaleByProperty.h"
 #include "mitkResliceMethodProperty.h"
 #include "mitkRenderingManager.h"
 
 #include "mitkTbssImage.h"
 #include "mitkPlanarFigure.h"
 #include "mitkFiberBundle.h"
 #include "QmitkDataStorageComboBox.h"
 #include "QmitkStdMultiWidget.h"
 #include "mitkFiberBundleInteractor.h"
 #include "mitkPlanarFigureInteractor.h"
 #include <mitkQBallImage.h>
 #include <mitkTensorImage.h>
 #include <mitkImage.h>
 #include <mitkDiffusionPropertyHelper.h>
 #include <mitkConnectomicsNetwork.h>
 #include "mitkGlobalInteraction.h"
 #include "usModuleRegistry.h"
 
 #include "mitkPlaneGeometry.h"
 
 #include "berryIWorkbenchWindow.h"
 #include "berryIWorkbenchPage.h"
 #include "berryISelectionService.h"
 #include "berryConstants.h"
 #include "berryPlatformUI.h"
 
 #include "itkRGBAPixel.h"
 #include <itkTractDensityImageFilter.h>
 
 #include "qwidgetaction.h"
 #include "qcolordialog.h"
 #include <QRgb>
 #include <itkMultiThreader.h>
 
 #define ROUND(a) ((a)>0 ? (int)((a)+0.5) : -(int)(0.5-(a)))
 
 const std::string QmitkControlVisualizationPropertiesView::VIEW_ID = "org.mitk.views.controlvisualizationpropertiesview";
 
 using namespace berry;
 
 QmitkControlVisualizationPropertiesView::QmitkControlVisualizationPropertiesView()
     : QmitkFunctionality(),
       m_Controls(NULL),
       m_MultiWidget(NULL),
       m_NodeUsedForOdfVisualization(NULL),
       m_IconTexOFF(new QIcon(":/QmitkDiffusionImaging/texIntOFFIcon.png")),
       m_IconTexON(new QIcon(":/QmitkDiffusionImaging/texIntONIcon.png")),
       m_IconGlyOFF_T(new QIcon(":/QmitkDiffusionImaging/glyphsoff_T.png")),
       m_IconGlyON_T(new QIcon(":/QmitkDiffusionImaging/glyphson_T.png")),
       m_IconGlyOFF_C(new QIcon(":/QmitkDiffusionImaging/glyphsoff_C.png")),
       m_IconGlyON_C(new QIcon(":/QmitkDiffusionImaging/glyphson_C.png")),
       m_IconGlyOFF_S(new QIcon(":/QmitkDiffusionImaging/glyphsoff_S.png")),
       m_IconGlyON_S(new QIcon(":/QmitkDiffusionImaging/glyphson_S.png")),
       m_CurrentSelection(0),
       m_CurrentPickingNode(0),
       m_GlyIsOn_S(false),
       m_GlyIsOn_C(false),
       m_GlyIsOn_T(false),
       m_FiberBundleObserverTag(0),
       m_FiberBundleObserveOpacityTag(0),
       m_Color(NULL)
 {
     currentThickSlicesMode = 1;
     m_MyMenu = NULL;
     int numThread = itk::MultiThreader::GetGlobalMaximumNumberOfThreads();
     if (numThread > 12)
         numThread = 12;
     itk::MultiThreader::SetGlobalDefaultNumberOfThreads(numThread);
 }
 
 QmitkControlVisualizationPropertiesView::~QmitkControlVisualizationPropertiesView()
 {
     if(m_SlicesRotationObserverTag1 )
     {
         mitk::SlicesCoordinator::Pointer coordinator = m_MultiWidget->GetSlicesRotator();
         if( coordinator.IsNotNull() )
             coordinator->RemoveObserver(m_SlicesRotationObserverTag1);
     }
     if( m_SlicesRotationObserverTag2)
     {
         mitk::SlicesCoordinator::Pointer coordinator = m_MultiWidget->GetSlicesRotator();
         if( coordinator.IsNotNull() )
             coordinator->RemoveObserver(m_SlicesRotationObserverTag1);
     }
 
     this->GetSite()->GetWorkbenchWindow()->GetSelectionService()->RemovePostSelectionListener(/*"org.mitk.views.datamanager",*/ m_SelListener.data());
 }
 
 void QmitkControlVisualizationPropertiesView::OnThickSlicesModeSelected( QAction* action )
 {
     currentThickSlicesMode = action->data().toInt();
 
     switch(currentThickSlicesMode)
     {
     default:
     case 1:
         this->m_Controls->m_TSMenu->setText("MIP");
         break;
     case 2:
         this->m_Controls->m_TSMenu->setText("SUM");
         break;
     case 3:
         this->m_Controls->m_TSMenu->setText("WEIGH");
         break;
     }
 
     mitk::DataNode* n;
     n = this->m_MultiWidget->GetWidgetPlane1(); if(n) n->SetProperty( "reslice.thickslices", mitk::ResliceMethodProperty::New( currentThickSlicesMode ) );
     n = this->m_MultiWidget->GetWidgetPlane2(); if(n) n->SetProperty( "reslice.thickslices", mitk::ResliceMethodProperty::New( currentThickSlicesMode ) );
     n = this->m_MultiWidget->GetWidgetPlane3(); if(n) n->SetProperty( "reslice.thickslices", mitk::ResliceMethodProperty::New( currentThickSlicesMode ) );
 
     mitk::BaseRenderer::Pointer renderer =
             this->GetActiveStdMultiWidget()->GetRenderWindow1()->GetRenderer();
     if(renderer.IsNotNull())
     {
         renderer->SendUpdateSlice();
     }
     renderer = this->GetActiveStdMultiWidget()->GetRenderWindow2()->GetRenderer();
     if(renderer.IsNotNull())
     {
         renderer->SendUpdateSlice();
     }
     renderer = this->GetActiveStdMultiWidget()->GetRenderWindow3()->GetRenderer();
     if(renderer.IsNotNull())
     {
         renderer->SendUpdateSlice();
     }
     renderer->GetRenderingManager()->RequestUpdateAll();
 }
 
 void QmitkControlVisualizationPropertiesView::OnTSNumChanged(int num)
 {
     if(num==0)
     {
         mitk::DataNode* n;
         n = this->m_MultiWidget->GetWidgetPlane1();
         if(n) n->SetProperty( "reslice.thickslices", mitk::ResliceMethodProperty::New( 0 ) );
         if(n) n->SetProperty( "reslice.thickslices.num", mitk::IntProperty::New( num ) );
         if(n) n->SetProperty( "reslice.thickslices.showarea", mitk::BoolProperty::New( false ) );
 
         n = this->m_MultiWidget->GetWidgetPlane2();
         if(n) n->SetProperty( "reslice.thickslices", mitk::ResliceMethodProperty::New( 0 ) );
         if(n) n->SetProperty( "reslice.thickslices.num", mitk::IntProperty::New( num ) );
         if(n) n->SetProperty( "reslice.thickslices.showarea", mitk::BoolProperty::New( false ) );
 
         n = this->m_MultiWidget->GetWidgetPlane3();
         if(n) n->SetProperty( "reslice.thickslices", mitk::ResliceMethodProperty::New( 0 ) );
         if(n) n->SetProperty( "reslice.thickslices.num", mitk::IntProperty::New( num ) );
         if(n) n->SetProperty( "reslice.thickslices.showarea", mitk::BoolProperty::New( false ) );
     }
     else
     {
         mitk::DataNode* n;
         n = this->m_MultiWidget->GetWidgetPlane1();
         if(n) n->SetProperty( "reslice.thickslices", mitk::ResliceMethodProperty::New( currentThickSlicesMode ) );
         if(n) n->SetProperty( "reslice.thickslices.num", mitk::IntProperty::New( num ) );
         if(n) n->SetProperty( "reslice.thickslices.showarea", mitk::BoolProperty::New( (num>0) ) );
 
         n = this->m_MultiWidget->GetWidgetPlane2();
         if(n) n->SetProperty( "reslice.thickslices", mitk::ResliceMethodProperty::New( currentThickSlicesMode ) );
         if(n) n->SetProperty( "reslice.thickslices.num", mitk::IntProperty::New( num ) );
         if(n) n->SetProperty( "reslice.thickslices.showarea", mitk::BoolProperty::New( (num>0) ) );
 
         n = this->m_MultiWidget->GetWidgetPlane3();
         if(n) n->SetProperty( "reslice.thickslices", mitk::ResliceMethodProperty::New( currentThickSlicesMode ) );
         if(n) n->SetProperty( "reslice.thickslices.num", mitk::IntProperty::New( num ) );
         if(n) n->SetProperty( "reslice.thickslices.showarea", mitk::BoolProperty::New( (num>0) ) );
     }
 
     m_TSLabel->setText(QString::number(num*2+1));
 
     mitk::BaseRenderer::Pointer renderer = this->GetActiveStdMultiWidget()->GetRenderWindow1()->GetRenderer();
     if(renderer.IsNotNull())
         renderer->SendUpdateSlice();
 
     renderer = this->GetActiveStdMultiWidget()->GetRenderWindow2()->GetRenderer();
     if(renderer.IsNotNull())
         renderer->SendUpdateSlice();
 
     renderer = this->GetActiveStdMultiWidget()->GetRenderWindow3()->GetRenderer();
     if(renderer.IsNotNull())
         renderer->SendUpdateSlice();
 
     renderer->GetRenderingManager()->RequestUpdateAll(mitk::RenderingManager::REQUEST_UPDATE_2DWINDOWS);
 }
 
 void QmitkControlVisualizationPropertiesView::CreateQtPartControl(QWidget *parent)
 {
     if (!m_Controls)
     {
         // create GUI widgets
         m_Controls = new Ui::QmitkControlVisualizationPropertiesViewControls;
         m_Controls->setupUi(parent);
         this->CreateConnections();
 
         // hide warning (ODFs in rotated planes)
         m_Controls->m_lblRotatedPlanesWarning->hide();
 
         m_MyMenu = new QMenu(parent);
         m_Controls->m_TSMenu->setMenu( m_MyMenu );
 
         QIcon iconFiberFade(":/QmitkDiffusionImaging/MapperEfx2D.png");
         m_Controls->m_FiberFading2D->setIcon(iconFiberFade);
 
 #ifndef DIFFUSION_IMAGING_EXTENDED
         int size = m_Controls->m_AdditionalScaling->count();
         for(int t=0; t<size; t++)
         {
             if(m_Controls->m_AdditionalScaling->itemText(t).toStdString() == "Scale by ASR")
             {
                 m_Controls->m_AdditionalScaling->removeItem(t);
             }
         }
 #endif
 
         m_Controls->m_ScalingFrame->setVisible(false);
         m_Controls->m_NormalizationFrame->setVisible(false);
     }
 }
 
 void QmitkControlVisualizationPropertiesView::StdMultiWidgetAvailable (QmitkStdMultiWidget &stdMultiWidget)
 {
     m_MultiWidget = &stdMultiWidget;
 
     if (m_MultiWidget)
     {
         mitk::SlicesCoordinator* coordinator = m_MultiWidget->GetSlicesRotator();
         if (coordinator)
         {
             itk::ReceptorMemberCommand<QmitkControlVisualizationPropertiesView>::Pointer command2 = itk::ReceptorMemberCommand<QmitkControlVisualizationPropertiesView>::New();
             command2->SetCallbackFunction( this, &QmitkControlVisualizationPropertiesView::SliceRotation );
             m_SlicesRotationObserverTag1 = coordinator->AddObserver( mitk::SliceRotationEvent(), command2 );
         }
 
         coordinator = m_MultiWidget->GetSlicesSwiveller();
         if (coordinator)
         {
             itk::ReceptorMemberCommand<QmitkControlVisualizationPropertiesView>::Pointer command2 = itk::ReceptorMemberCommand<QmitkControlVisualizationPropertiesView>::New();
             command2->SetCallbackFunction( this, &QmitkControlVisualizationPropertiesView::SliceRotation );
             m_SlicesRotationObserverTag2 = coordinator->AddObserver( mitk::SliceRotationEvent(), command2 );
         }
     }
 }
 
 void QmitkControlVisualizationPropertiesView::SliceRotation(const itk::EventObject&)
 {
     // test if plane rotated
     if( m_GlyIsOn_T || m_GlyIsOn_C || m_GlyIsOn_S )
     {
         if( this->IsPlaneRotated() )
         {
             // show label
             m_Controls->m_lblRotatedPlanesWarning->show();
         }
         else
         {
             //hide label
             m_Controls->m_lblRotatedPlanesWarning->hide();
         }
     }
 }
 
 void QmitkControlVisualizationPropertiesView::StdMultiWidgetNotAvailable()
 {
     m_MultiWidget = NULL;
 }
 
 void QmitkControlVisualizationPropertiesView::NodeRemoved(const mitk::DataNode* /*node*/)
 {
 }
 
 #include <mitkMessage.h>
 void QmitkControlVisualizationPropertiesView::CreateConnections()
 {
     if ( m_Controls )
     {
         connect( (QObject*)(m_Controls->m_VisibleOdfsON_T), SIGNAL(clicked()), this, SLOT(VisibleOdfsON_T()) );
         connect( (QObject*)(m_Controls->m_VisibleOdfsON_S), SIGNAL(clicked()), this, SLOT(VisibleOdfsON_S()) );
         connect( (QObject*)(m_Controls->m_VisibleOdfsON_C), SIGNAL(clicked()), this, SLOT(VisibleOdfsON_C()) );
         connect( (QObject*)(m_Controls->m_ShowMaxNumber), SIGNAL(editingFinished()), this, SLOT(ShowMaxNumberChanged()) );
         connect( (QObject*)(m_Controls->m_NormalizationDropdown), SIGNAL(currentIndexChanged(int)), this, SLOT(NormalizationDropdownChanged(int)) );
         connect( (QObject*)(m_Controls->m_ScalingFactor), SIGNAL(valueChanged(double)), this, SLOT(ScalingFactorChanged(double)) );
         connect( (QObject*)(m_Controls->m_AdditionalScaling), SIGNAL(currentIndexChanged(int)), this, SLOT(AdditionalScaling(int)) );
         connect( (QObject*)(m_Controls->m_ScalingCheckbox), SIGNAL(clicked()), this, SLOT(ScalingCheckbox()) );
         connect((QObject*) m_Controls->m_ResetColoring, SIGNAL(clicked()), (QObject*) this, SLOT(BundleRepresentationResetColoring()));
         connect((QObject*) m_Controls->m_FiberFading2D, SIGNAL(clicked()), (QObject*) this, SLOT( Fiber2DfadingEFX() ) );
         connect((QObject*) m_Controls->m_FiberThicknessSlider, SIGNAL(sliderReleased()), (QObject*) this, SLOT( FiberSlicingThickness2D() ) );
         connect((QObject*) m_Controls->m_FiberThicknessSlider, SIGNAL(valueChanged(int)), (QObject*) this, SLOT( FiberSlicingUpdateLabel(int) ));
         connect((QObject*) m_Controls->m_Crosshair, SIGNAL(clicked()), (QObject*) this, SLOT(SetInteractor()));
         connect((QObject*) m_Controls->m_LineWidth, SIGNAL(editingFinished()), (QObject*) this, SLOT(LineWidthChanged()));
         connect((QObject*) m_Controls->m_TubeWidth, SIGNAL(editingFinished()), (QObject*) this, SLOT(TubeRadiusChanged()));
     }
 }
 
 void QmitkControlVisualizationPropertiesView::Activated()
 {
 
 }
 
 void QmitkControlVisualizationPropertiesView::Deactivated()
 {
 
 }
 
 // set diffusion image channel to b0 volume
 void QmitkControlVisualizationPropertiesView::NodeAdded(const mitk::DataNode *node)
 {
     mitk::DataNode* notConst = const_cast<mitk::DataNode*>(node);
 
     bool isDiffusionImage( mitk::DiffusionPropertyHelper::IsDiffusionWeightedImage( dynamic_cast<mitk::Image *>(node->GetData())) );
 
     if (isDiffusionImage)
     {
         mitk::Image::Pointer dimg = dynamic_cast<mitk::Image*>(notConst->GetData());
 
         // if there is no b0 image in the dataset, the GetB0Indices() returns a vector of size 0
         // and hence we cannot set the Property directly to .front()
         int displayChannelPropertyValue = 0;
         mitk::BValueMapProperty* bmapproperty = static_cast<mitk::BValueMapProperty*>(dimg->GetProperty(mitk::DiffusionPropertyHelper::BVALUEMAPPROPERTYNAME.c_str()).GetPointer() );
         mitk::DiffusionPropertyHelper::BValueMapType map = bmapproperty->GetBValueMap();
         if( map[0].size() > 0)
             displayChannelPropertyValue = map[0].front();
 
         notConst->SetIntProperty("DisplayChannel", displayChannelPropertyValue );
     }
 }
 
 /* OnSelectionChanged is registered to SelectionService, therefore no need to
 implement SelectionService Listener explicitly */
 void QmitkControlVisualizationPropertiesView::OnSelectionChanged( std::vector<mitk::DataNode*> nodes )
 {
     m_Controls->m_BundleControlsFrame->setVisible(false);
     m_Controls->m_ImageControlsFrame->setVisible(false);
 
     if (nodes.size()>1) // only do stuff if one node is selected
         return;
 
     m_Controls->m_NumberGlyphsFrame->setVisible(false);
     m_Controls->m_GlyphFrame->setVisible(false);
     m_Controls->m_TSMenu->setVisible(false);
 
     m_SelectedNode = NULL;
 
     int numOdfImages = 0;
     for( std::vector<mitk::DataNode*>::iterator it = nodes.begin(); it != nodes.end(); ++it )
     {
         mitk::DataNode::Pointer node = *it;
         if(node.IsNull())
             continue;
 
         mitk::BaseData* nodeData = node->GetData();
         if(nodeData == NULL)
             continue;
 
         m_SelectedNode = node;
 
         if (dynamic_cast<mitk::FiberBundle*>(nodeData))
         {
             // handle fiber bundle property observers
             if (m_Color.IsNotNull())
                 m_Color->RemoveObserver(m_FiberBundleObserverTag);
             itk::ReceptorMemberCommand<QmitkControlVisualizationPropertiesView>::Pointer command = itk::ReceptorMemberCommand<QmitkControlVisualizationPropertiesView>::New();
             command->SetCallbackFunction( this, &QmitkControlVisualizationPropertiesView::SetFiberBundleCustomColor );
             m_Color = dynamic_cast<mitk::ColorProperty*>(node->GetProperty("color", NULL));
             if (m_Color.IsNotNull())
                 m_FiberBundleObserverTag = m_Color->AddObserver( itk::ModifiedEvent(), command );
 
             if (m_Opacity.IsNotNull())
                 m_Opacity->RemoveObserver(m_FiberBundleObserveOpacityTag);
             itk::ReceptorMemberCommand<QmitkControlVisualizationPropertiesView>::Pointer command2 = itk::ReceptorMemberCommand<QmitkControlVisualizationPropertiesView>::New();
             command2->SetCallbackFunction( this, &QmitkControlVisualizationPropertiesView::SetFiberBundleOpacity );
             m_Opacity = dynamic_cast<mitk::FloatProperty*>(node->GetProperty("opacity", NULL));
             if (m_Opacity.IsNotNull())
                 m_FiberBundleObserveOpacityTag = m_Opacity->AddObserver( itk::ModifiedEvent(), command2 );
 
             m_Controls->m_BundleControlsFrame->setVisible(true);
 
             // ???
             if(m_CurrentPickingNode != 0 && node.GetPointer() != m_CurrentPickingNode)
                 m_Controls->m_Crosshair->setEnabled(false);
             else
                 m_Controls->m_Crosshair->setEnabled(true);
 
             int width;
             node->GetIntProperty("shape.linewidth", width);
             m_Controls->m_LineWidth->setValue(width);
 
             float radius;
             node->GetFloatProperty("shape.tuberadius", radius);
             m_Controls->m_TubeWidth->setValue(radius);
 
             float range;
             node->GetFloatProperty("Fiber2DSliceThickness",range);
             mitk::FiberBundle::Pointer fib = dynamic_cast<mitk::FiberBundle*>(node->GetData());
             mitk::BaseGeometry::Pointer geo = fib->GetGeometry();
             mitk::ScalarType max = geo->GetExtentInMM(0);
             max = std::max(max, geo->GetExtentInMM(1));
             max = std::max(max, geo->GetExtentInMM(2));
 
             m_Controls->m_FiberThicknessSlider->setMaximum(max * 10);
             m_Controls->m_FiberThicknessSlider->setValue(range * 10);
-            m_Controls->m_FiberThicknessSlider->setFocus();
         }
         else if(dynamic_cast<mitk::QBallImage*>(nodeData) || dynamic_cast<mitk::TensorImage*>(nodeData))
         {
             m_Controls->m_ImageControlsFrame->setVisible(true);
             m_Controls->m_NumberGlyphsFrame->setVisible(true);
             m_Controls->m_GlyphFrame->setVisible(true);
 
             if(m_NodeUsedForOdfVisualization.IsNotNull())
             {
                 m_NodeUsedForOdfVisualization->SetBoolProperty("VisibleOdfs_S", false);
                 m_NodeUsedForOdfVisualization->SetBoolProperty("VisibleOdfs_C", false);
                 m_NodeUsedForOdfVisualization->SetBoolProperty("VisibleOdfs_T", false);
             }
             m_NodeUsedForOdfVisualization = node;
             m_NodeUsedForOdfVisualization->SetBoolProperty("VisibleOdfs_S", m_GlyIsOn_S);
             m_NodeUsedForOdfVisualization->SetBoolProperty("VisibleOdfs_C", m_GlyIsOn_C);
             m_NodeUsedForOdfVisualization->SetBoolProperty("VisibleOdfs_T", m_GlyIsOn_T);
 
             int val;
             node->GetIntProperty("ShowMaxNumber", val);
             m_Controls->m_ShowMaxNumber->setValue(val);
 
             m_Controls->m_NormalizationDropdown->setCurrentIndex(dynamic_cast<mitk::EnumerationProperty*>(node->GetProperty("Normalization"))->GetValueAsId());
 
             float fval;
             node->GetFloatProperty("Scaling",fval);
             m_Controls->m_ScalingFactor->setValue(fval);
 
             m_Controls->m_AdditionalScaling->setCurrentIndex(dynamic_cast<mitk::EnumerationProperty*>(node->GetProperty("ScaleBy"))->GetValueAsId());
 
             numOdfImages++;
         }
         else if(dynamic_cast<mitk::PlanarFigure*>(nodeData))
         {
             PlanarFigureFocus();
         }
         else if( dynamic_cast<mitk::Image*>(nodeData) )
         {
             m_Controls->m_ImageControlsFrame->setVisible(true);
             m_Controls->m_TSMenu->setVisible(true);
         }
     }
 
     if( nodes.empty() )
         return;
 
     mitk::DataNode::Pointer node = nodes.at(0);
 
     if( node.IsNull() )
         return;
 
     QMenu *myMenu = m_MyMenu;
     myMenu->clear();
 
     QActionGroup* thickSlicesActionGroup = new QActionGroup(myMenu);
     thickSlicesActionGroup->setExclusive(true);
 
     int currentTSMode = 0;
     {
         mitk::ResliceMethodProperty::Pointer m = dynamic_cast<mitk::ResliceMethodProperty*>(node->GetProperty( "reslice.thickslices" ));
         if( m.IsNotNull() )
             currentTSMode = m->GetValueAsId();
     }
 
     int maxTS = 30;
 
     for( std::vector<mitk::DataNode*>::iterator it = nodes.begin(); it != nodes.end(); ++it )
     {
         mitk::Image* image = dynamic_cast<mitk::Image*>((*it)->GetData());
         if (image)
         {
             int size = std::max(image->GetDimension(0), std::max(image->GetDimension(1), image->GetDimension(2)));
             if (size>maxTS)
                 maxTS=size;
         }
     }
     maxTS /= 2;
 
     int currentNum = 0;
     {
         mitk::IntProperty::Pointer m = dynamic_cast<mitk::IntProperty*>(node->GetProperty( "reslice.thickslices.num" ));
         if( m.IsNotNull() )
         {
             currentNum = m->GetValue();
             if(currentNum < 0) currentNum = 0;
             if(currentNum > maxTS) currentNum = maxTS;
         }
     }
 
     if(currentTSMode==0)
         currentNum=0;
 
     QSlider *m_TSSlider = new QSlider(myMenu);
     m_TSSlider->setMinimum(0);
     m_TSSlider->setMaximum(maxTS-1);
     m_TSSlider->setValue(currentNum);
 
     m_TSSlider->setOrientation(Qt::Horizontal);
 
     connect( m_TSSlider, SIGNAL( valueChanged(int) ), this, SLOT( OnTSNumChanged(int) ) );
 
     QHBoxLayout* _TSLayout = new QHBoxLayout;
     _TSLayout->setContentsMargins(4,4,4,4);
     _TSLayout->addWidget(m_TSSlider);
     _TSLayout->addWidget(m_TSLabel=new QLabel(QString::number(currentNum*2+1),myMenu));
 
     QWidget* _TSWidget = new QWidget;
     _TSWidget->setLayout(_TSLayout);
 
     QActionGroup* thickSliceModeActionGroup = new QActionGroup(myMenu);
     thickSliceModeActionGroup->setExclusive(true);
 
     QWidgetAction *m_TSSliderAction = new QWidgetAction(myMenu);
     m_TSSliderAction->setDefaultWidget(_TSWidget);
     myMenu->addAction(m_TSSliderAction);
 
     QAction* mipThickSlicesAction = new QAction(myMenu);
     mipThickSlicesAction->setActionGroup(thickSliceModeActionGroup);
     mipThickSlicesAction->setText("MIP (max. intensity proj.)");
     mipThickSlicesAction->setCheckable(true);
     mipThickSlicesAction->setChecked(currentThickSlicesMode==1);
     mipThickSlicesAction->setData(1);
     myMenu->addAction( mipThickSlicesAction );
 
     QAction* sumThickSlicesAction = new QAction(myMenu);
     sumThickSlicesAction->setActionGroup(thickSliceModeActionGroup);
     sumThickSlicesAction->setText("SUM (sum intensity proj.)");
     sumThickSlicesAction->setCheckable(true);
     sumThickSlicesAction->setChecked(currentThickSlicesMode==2);
     sumThickSlicesAction->setData(2);
     myMenu->addAction( sumThickSlicesAction );
 
     QAction* weightedThickSlicesAction = new QAction(myMenu);
     weightedThickSlicesAction->setActionGroup(thickSliceModeActionGroup);
     weightedThickSlicesAction->setText("WEIGHTED (gaussian proj.)");
     weightedThickSlicesAction->setCheckable(true);
     weightedThickSlicesAction->setChecked(currentThickSlicesMode==3);
     weightedThickSlicesAction->setData(3);
     myMenu->addAction( weightedThickSlicesAction );
 
     connect( thickSliceModeActionGroup, SIGNAL(triggered(QAction*)), this, SLOT(OnThickSlicesModeSelected(QAction*)) );
 }
 
 void QmitkControlVisualizationPropertiesView::VisibleOdfsON_S()
 {
     m_GlyIsOn_S = m_Controls->m_VisibleOdfsON_S->isChecked();
     if (m_NodeUsedForOdfVisualization.IsNull())
     {
         MITK_WARN << "ODF visualization activated but m_NodeUsedForOdfVisualization is NULL";
         return;
     }
     m_NodeUsedForOdfVisualization->SetBoolProperty("VisibleOdfs_S", m_GlyIsOn_S);
     mitk::RenderingManager::GetInstance()->RequestUpdateAll();
 }
 
 void QmitkControlVisualizationPropertiesView::VisibleOdfsON_T()
 {
     m_GlyIsOn_T = m_Controls->m_VisibleOdfsON_T->isChecked();
     if (m_NodeUsedForOdfVisualization.IsNull())
     {
         MITK_WARN << "ODF visualization activated but m_NodeUsedForOdfVisualization is NULL";
         return;
     }
     m_NodeUsedForOdfVisualization->SetBoolProperty("VisibleOdfs_T", m_GlyIsOn_T);
     mitk::RenderingManager::GetInstance()->RequestUpdateAll();
 }
 
 void QmitkControlVisualizationPropertiesView::VisibleOdfsON_C()
 {
     m_GlyIsOn_C = m_Controls->m_VisibleOdfsON_C->isChecked();
     if (m_NodeUsedForOdfVisualization.IsNull())
     {
         MITK_WARN << "ODF visualization activated but m_NodeUsedForOdfVisualization is NULL";
         return;
     }
     m_NodeUsedForOdfVisualization->SetBoolProperty("VisibleOdfs_C", m_GlyIsOn_C);
     mitk::RenderingManager::GetInstance()->RequestUpdateAll();
 }
 
 bool QmitkControlVisualizationPropertiesView::IsPlaneRotated()
 {
     mitk::Image* currentImage = dynamic_cast<mitk::Image* >( m_NodeUsedForOdfVisualization->GetData() );
     if( currentImage == NULL )
     {
         MITK_ERROR << " Casting problems. Returning false";
         return false;
     }
 
     mitk::Vector3D imageNormal0 = currentImage->GetSlicedGeometry()->GetAxisVector(0);
     mitk::Vector3D imageNormal1 = currentImage->GetSlicedGeometry()->GetAxisVector(1);
     mitk::Vector3D imageNormal2 = currentImage->GetSlicedGeometry()->GetAxisVector(2);
     imageNormal0.Normalize();
     imageNormal1.Normalize();
     imageNormal2.Normalize();
 
     double eps = 0.000001;
     // for all 2D renderwindows of m_MultiWidget check alignment
     {
         mitk::PlaneGeometry::ConstPointer displayPlane = dynamic_cast<const mitk::PlaneGeometry*>( m_MultiWidget->GetRenderWindow1()->GetRenderer()->GetCurrentWorldGeometry2D() );
         if (displayPlane.IsNull()) return false;
         mitk::Vector3D normal       = displayPlane->GetNormal();
         normal.Normalize();
         int test = 0;
         if( fabs(fabs(dot_product(normal.GetVnlVector(),imageNormal0.GetVnlVector()))-1) > eps )
             test++;
         if( fabs(fabs(dot_product(normal.GetVnlVector(),imageNormal1.GetVnlVector()))-1) > eps )
             test++;
         if( fabs(fabs(dot_product(normal.GetVnlVector(),imageNormal2.GetVnlVector()))-1) > eps )
             test++;
         if (test==3)
             return true;
     }
     {
         mitk::PlaneGeometry::ConstPointer displayPlane = dynamic_cast<const mitk::PlaneGeometry*>( m_MultiWidget->GetRenderWindow2()->GetRenderer()->GetCurrentWorldGeometry2D() );
         if (displayPlane.IsNull()) return false;
         mitk::Vector3D normal       = displayPlane->GetNormal();
         normal.Normalize();
         int test = 0;
         if( fabs(fabs(dot_product(normal.GetVnlVector(),imageNormal0.GetVnlVector()))-1) > eps )
             test++;
         if( fabs(fabs(dot_product(normal.GetVnlVector(),imageNormal1.GetVnlVector()))-1) > eps )
             test++;
         if( fabs(fabs(dot_product(normal.GetVnlVector(),imageNormal2.GetVnlVector()))-1) > eps )
             test++;
         if (test==3)
             return true;
     }
     {
         mitk::PlaneGeometry::ConstPointer displayPlane = dynamic_cast<const mitk::PlaneGeometry*>( m_MultiWidget->GetRenderWindow3()->GetRenderer()->GetCurrentWorldGeometry2D() );
         if (displayPlane.IsNull()) return false;
         mitk::Vector3D normal       = displayPlane->GetNormal();
         normal.Normalize();
         int test = 0;
         if( fabs(fabs(dot_product(normal.GetVnlVector(),imageNormal0.GetVnlVector()))-1) > eps )
             test++;
         if( fabs(fabs(dot_product(normal.GetVnlVector(),imageNormal1.GetVnlVector()))-1) > eps )
             test++;
         if( fabs(fabs(dot_product(normal.GetVnlVector(),imageNormal2.GetVnlVector()))-1) > eps )
             test++;
         if (test==3)
             return true;
     }
 
     return false;
 }
 
 void QmitkControlVisualizationPropertiesView::ShowMaxNumberChanged()
 {
     int maxNr = m_Controls->m_ShowMaxNumber->value();
     if ( maxNr < 1 )
     {
         m_Controls->m_ShowMaxNumber->setValue( 1 );
         maxNr = 1;
     }
 
     if (dynamic_cast<mitk::QBallImage*>(m_SelectedNode->GetData()) || dynamic_cast<mitk::TensorImage*>(m_SelectedNode->GetData()))
         m_SelectedNode->SetIntProperty("ShowMaxNumber", maxNr);
 
     mitk::RenderingManager::GetInstance()->RequestUpdateAll();
 }
 
 void QmitkControlVisualizationPropertiesView::NormalizationDropdownChanged(int normDropdown)
 {
     typedef mitk::OdfNormalizationMethodProperty PropType;
     PropType::Pointer normMeth = PropType::New();
 
     switch(normDropdown)
     {
     case 0:
         normMeth->SetNormalizationToMinMax();
         break;
     case 1:
         normMeth->SetNormalizationToMax();
         break;
     case 2:
         normMeth->SetNormalizationToNone();
         break;
     case 3:
         normMeth->SetNormalizationToGlobalMax();
         break;
     default:
         normMeth->SetNormalizationToMinMax();
     }
 
     if (dynamic_cast<mitk::QBallImage*>(m_SelectedNode->GetData()) || dynamic_cast<mitk::TensorImage*>(m_SelectedNode->GetData()))
         m_SelectedNode->SetProperty("Normalization", normMeth.GetPointer());
 
     mitk::RenderingManager::GetInstance()->RequestUpdateAll();
 }
 
 void QmitkControlVisualizationPropertiesView::ScalingFactorChanged(double scalingFactor)
 {
     if (dynamic_cast<mitk::QBallImage*>(m_SelectedNode->GetData()) || dynamic_cast<mitk::TensorImage*>(m_SelectedNode->GetData()))
         m_SelectedNode->SetFloatProperty("Scaling", scalingFactor);
 
     if(m_MultiWidget)
         m_MultiWidget->RequestUpdate();
 }
 
 void QmitkControlVisualizationPropertiesView::AdditionalScaling(int additionalScaling)
 {
 
     typedef mitk::OdfScaleByProperty PropType;
     PropType::Pointer scaleBy = PropType::New();
 
     switch(additionalScaling)
     {
     case 0:
         scaleBy->SetScaleByNothing();
         break;
     case 1:
         scaleBy->SetScaleByGFA();
         //m_Controls->params_frame->setVisible(true);
         break;
 #ifdef DIFFUSION_IMAGING_EXTENDED
     case 2:
         scaleBy->SetScaleByPrincipalCurvature();
         // commented in for SPIE paper, Principle curvature scaling
         //m_Controls->params_frame->setVisible(true);
         break;
 #endif
     default:
         scaleBy->SetScaleByNothing();
     }
 
     if (dynamic_cast<mitk::QBallImage*>(m_SelectedNode->GetData()) || dynamic_cast<mitk::TensorImage*>(m_SelectedNode->GetData()))
         m_SelectedNode->SetProperty("Normalization", scaleBy.GetPointer());
 
     mitk::RenderingManager::GetInstance()->RequestUpdateAll();
 }
 
 void QmitkControlVisualizationPropertiesView::ScalingCheckbox()
 {
     m_Controls->m_ScalingFrame->setVisible(
                 m_Controls->m_ScalingCheckbox->isChecked());
 
     if(!m_Controls->m_ScalingCheckbox->isChecked())
     {
         m_Controls->m_AdditionalScaling->setCurrentIndex(0);
         m_Controls->m_ScalingFactor->setValue(1.0);
     }
 }
 
 void QmitkControlVisualizationPropertiesView::Fiber2DfadingEFX()
 {
     if (m_SelectedNode && dynamic_cast<mitk::FiberBundle*>(m_SelectedNode->GetData()) )
     {
         bool currentMode;
         m_SelectedNode->GetBoolProperty("Fiber2DfadeEFX", currentMode);
         m_SelectedNode->SetProperty("Fiber2DfadeEFX", mitk::BoolProperty::New(!currentMode));
         dynamic_cast<mitk::FiberBundle*>(m_SelectedNode->GetData())->RequestUpdate2D();
         mitk::RenderingManager::GetInstance()->RequestUpdateAll();
     }
 }
 
 void QmitkControlVisualizationPropertiesView::FiberSlicingThickness2D()
 {
     if (m_SelectedNode && dynamic_cast<mitk::FiberBundle*>(m_SelectedNode->GetData()))
     {
         float fibThickness = m_Controls->m_FiberThicknessSlider->value() * 0.1;
         float currentThickness = 0;
         m_SelectedNode->GetFloatProperty("Fiber2DSliceThickness", currentThickness);
         if (fabs(fibThickness-currentThickness)<0.001)
             return;
         m_SelectedNode->SetProperty("Fiber2DSliceThickness", mitk::FloatProperty::New(fibThickness));
         dynamic_cast<mitk::FiberBundle*>(m_SelectedNode->GetData())->RequestUpdate2D();
         mitk::RenderingManager::GetInstance()->RequestUpdateAll();
     }
 }
 
 void QmitkControlVisualizationPropertiesView::FiberSlicingUpdateLabel(int value)
 {
     QString label = "Range %1 mm";
     label = label.arg(value * 0.1);
     m_Controls->label_range->setText(label);
     FiberSlicingThickness2D();
 }
 
 void QmitkControlVisualizationPropertiesView::SetFiberBundleOpacity(const itk::EventObject& /*e*/)
 {
     if(m_SelectedNode)
     {
         mitk::FiberBundle::Pointer fib = dynamic_cast<mitk::FiberBundle*>(m_SelectedNode->GetData());
         fib->RequestUpdate();
         mitk::RenderingManager::GetInstance()->RequestUpdateAll();
     }
 }
 
 void QmitkControlVisualizationPropertiesView::SetFiberBundleCustomColor(const itk::EventObject& /*e*/)
 {
     if(m_SelectedNode && dynamic_cast<mitk::FiberBundle*>(m_SelectedNode->GetData()))
     {
         float color[3];
         m_SelectedNode->GetColor(color);
         mitk::FiberBundle::Pointer fib = dynamic_cast<mitk::FiberBundle*>(m_SelectedNode->GetData());
         fib->SetFiberColors(color[0]*255, color[1]*255, color[2]*255);
         mitk::RenderingManager::GetInstance()->RequestUpdateAll();
     }
 }
 
 void QmitkControlVisualizationPropertiesView::BundleRepresentationResetColoring()
 {
     if(m_SelectedNode && dynamic_cast<mitk::FiberBundle*>(m_SelectedNode->GetData()))
     {
         mitk::FiberBundle::Pointer fib = dynamic_cast<mitk::FiberBundle*>(m_SelectedNode->GetData());
         fib->ColorFibersByOrientation();
         mitk::RenderingManager::GetInstance()->RequestUpdateAll();
     }
 }
 
 void QmitkControlVisualizationPropertiesView::PlanarFigureFocus()
 {
     if(m_SelectedNode)
     {
         mitk::PlanarFigure* _PlanarFigure = 0;
         _PlanarFigure = dynamic_cast<mitk::PlanarFigure*> (m_SelectedNode->GetData());
 
         if (_PlanarFigure && _PlanarFigure->GetPlaneGeometry())
         {
 
             QmitkRenderWindow* selectedRenderWindow = 0;
             bool PlanarFigureInitializedWindow = false;
 
             QmitkRenderWindow* RenderWindow1 =
                     this->GetActiveStdMultiWidget()->GetRenderWindow1();
 
             if (m_SelectedNode->GetBoolProperty("PlanarFigureInitializedWindow",
                                                 PlanarFigureInitializedWindow, RenderWindow1->GetRenderer()))
             {
                 selectedRenderWindow = RenderWindow1;
             }
 
             QmitkRenderWindow* RenderWindow2 =
                     this->GetActiveStdMultiWidget()->GetRenderWindow2();
 
             if (!selectedRenderWindow && m_SelectedNode->GetBoolProperty(
                         "PlanarFigureInitializedWindow", PlanarFigureInitializedWindow,
                         RenderWindow2->GetRenderer()))
             {
                 selectedRenderWindow = RenderWindow2;
             }
 
             QmitkRenderWindow* RenderWindow3 =
                     this->GetActiveStdMultiWidget()->GetRenderWindow3();
 
             if (!selectedRenderWindow && m_SelectedNode->GetBoolProperty(
                         "PlanarFigureInitializedWindow", PlanarFigureInitializedWindow,
                         RenderWindow3->GetRenderer()))
             {
                 selectedRenderWindow = RenderWindow3;
             }
 
             QmitkRenderWindow* RenderWindow4 =
                     this->GetActiveStdMultiWidget()->GetRenderWindow4();
 
             if (!selectedRenderWindow && m_SelectedNode->GetBoolProperty(
                         "PlanarFigureInitializedWindow", PlanarFigureInitializedWindow,
                         RenderWindow4->GetRenderer()))
             {
                 selectedRenderWindow = RenderWindow4;
             }
 
             const mitk::PlaneGeometry* _PlaneGeometry = _PlanarFigure->GetPlaneGeometry();
 
             mitk::VnlVector normal = _PlaneGeometry->GetNormalVnl();
 
             mitk::Geometry2D::ConstPointer worldGeometry1 =
                     RenderWindow1->GetRenderer()->GetCurrentWorldGeometry2D();
             mitk::PlaneGeometry::ConstPointer _Plane1 =
                     dynamic_cast<const mitk::PlaneGeometry*>( worldGeometry1.GetPointer() );
             mitk::VnlVector normal1 = _Plane1->GetNormalVnl();
 
             mitk::Geometry2D::ConstPointer worldGeometry2 =
                     RenderWindow2->GetRenderer()->GetCurrentWorldGeometry2D();
             mitk::PlaneGeometry::ConstPointer _Plane2 =
                     dynamic_cast<const mitk::PlaneGeometry*>( worldGeometry2.GetPointer() );
             mitk::VnlVector normal2 = _Plane2->GetNormalVnl();
 
             mitk::Geometry2D::ConstPointer worldGeometry3 =
                     RenderWindow3->GetRenderer()->GetCurrentWorldGeometry2D();
             mitk::PlaneGeometry::ConstPointer _Plane3 =
                     dynamic_cast<const mitk::PlaneGeometry*>( worldGeometry3.GetPointer() );
             mitk::VnlVector normal3 = _Plane3->GetNormalVnl();
 
             normal[0]  = fabs(normal[0]);  normal[1]  = fabs(normal[1]);  normal[2]  = fabs(normal[2]);
             normal1[0] = fabs(normal1[0]); normal1[1] = fabs(normal1[1]); normal1[2] = fabs(normal1[2]);
             normal2[0] = fabs(normal2[0]); normal2[1] = fabs(normal2[1]); normal2[2] = fabs(normal2[2]);
             normal3[0] = fabs(normal3[0]); normal3[1] = fabs(normal3[1]); normal3[2] = fabs(normal3[2]);
 
             double ang1 = angle(normal, normal1);
             double ang2 = angle(normal, normal2);
             double ang3 = angle(normal, normal3);
 
             if(ang1 < ang2 && ang1 < ang3)
             {
                 selectedRenderWindow = RenderWindow1;
             }
             else
             {
                 if(ang2 < ang3)
                 {
                     selectedRenderWindow = RenderWindow2;
                 }
                 else
                 {
                     selectedRenderWindow = RenderWindow3;
                 }
             }
 
             // make node visible
             if (selectedRenderWindow)
             {
                 const mitk::Point3D& centerP = _PlaneGeometry->GetOrigin();
                 selectedRenderWindow->GetSliceNavigationController()->ReorientSlices(
                             centerP, _PlaneGeometry->GetNormal());
             }
         }
 
         // set interactor for new node (if not already set)
         mitk::PlanarFigureInteractor::Pointer figureInteractor
                 = dynamic_cast<mitk::PlanarFigureInteractor*>(m_SelectedNode->GetDataInteractor().GetPointer());
 
         if(figureInteractor.IsNull())
         {
             figureInteractor = mitk::PlanarFigureInteractor::New();
             us::Module* planarFigureModule = us::ModuleRegistry::GetModule( "MitkPlanarFigure" );
             figureInteractor->LoadStateMachine("PlanarFigureInteraction.xml", planarFigureModule );
             figureInteractor->SetEventConfig( "PlanarFigureConfig.xml", planarFigureModule );
             figureInteractor->SetDataNode( m_SelectedNode );
         }
 
         m_SelectedNode->SetProperty("planarfigure.iseditable",mitk::BoolProperty::New(true));
     }
 }
 
 void QmitkControlVisualizationPropertiesView::SetInteractor()
 {
     typedef std::vector<mitk::DataNode*> Container;
     Container _NodeSet = this->GetDataManagerSelection();
     mitk::DataNode* node = 0;
     mitk::FiberBundle* bundle = 0;
     mitk::FiberBundleInteractor::Pointer bundleInteractor = 0;
 
     // finally add all nodes to the model
     for(Container::const_iterator it=_NodeSet.begin(); it!=_NodeSet.end()
         ; it++)
     {
         node = const_cast<mitk::DataNode*>(*it);
         bundle = dynamic_cast<mitk::FiberBundle*>(node->GetData());
 
         if(bundle)
         {
             bundleInteractor = dynamic_cast<mitk::FiberBundleInteractor*>(node->GetInteractor());
 
             if(bundleInteractor.IsNotNull())
                 mitk::GlobalInteraction::GetInstance()->RemoveInteractor(bundleInteractor);
 
             if(!m_Controls->m_Crosshair->isChecked())
             {
                 m_Controls->m_Crosshair->setChecked(false);
                 this->GetActiveStdMultiWidget()->GetRenderWindow4()->setCursor(Qt::ArrowCursor);
                 m_CurrentPickingNode = 0;
             }
             else
             {
                 m_Controls->m_Crosshair->setChecked(true);
                 bundleInteractor = mitk::FiberBundleInteractor::New("FiberBundleInteractor", node);
                 mitk::GlobalInteraction::GetInstance()->AddInteractor(bundleInteractor);
                 this->GetActiveStdMultiWidget()->GetRenderWindow4()->setCursor(Qt::CrossCursor);
                 m_CurrentPickingNode = node;
             }
 
         }
     }
 }
 
 void QmitkControlVisualizationPropertiesView::TubeRadiusChanged()
 {
     if(m_SelectedNode && dynamic_cast<mitk::FiberBundle*>(m_SelectedNode->GetData()))
     {
         float newRadius = m_Controls->m_TubeWidth->value();
         m_SelectedNode->SetFloatProperty("shape.tuberadius", newRadius);
         mitk::RenderingManager::GetInstance()->RequestUpdateAll();
     }
 }
 
 void QmitkControlVisualizationPropertiesView::LineWidthChanged()
 {
     if(m_SelectedNode && dynamic_cast<mitk::FiberBundle*>(m_SelectedNode->GetData()))
     {
         int newWidth = m_Controls->m_LineWidth->value();
         int currentWidth = 0;
         m_SelectedNode->GetIntProperty("shape.linewidth", currentWidth);
         if (currentWidth==newWidth)
             return;
         m_SelectedNode->SetIntProperty("shape.linewidth", newWidth);
         dynamic_cast<mitk::FiberBundle*>(m_SelectedNode->GetData())->RequestUpdate();
         mitk::RenderingManager::GetInstance()->RequestUpdateAll();
     }
 }
 
 void QmitkControlVisualizationPropertiesView::Welcome()
 {
     berry::PlatformUI::GetWorkbench()->GetIntroManager()->ShowIntro(
                 GetSite()->GetWorkbenchWindow(), false);
 }
diff --git a/Plugins/org.mitk.gui.qt.diffusionimaging/src/internal/QmitkControlVisualizationPropertiesViewControls.ui b/Plugins/org.mitk.gui.qt.diffusionimaging/src/internal/QmitkControlVisualizationPropertiesViewControls.ui
index 30c0704d5d..1babb00a07 100644
--- a/Plugins/org.mitk.gui.qt.diffusionimaging/src/internal/QmitkControlVisualizationPropertiesViewControls.ui
+++ b/Plugins/org.mitk.gui.qt.diffusionimaging/src/internal/QmitkControlVisualizationPropertiesViewControls.ui
@@ -1,722 +1,719 @@
 <?xml version="1.0" encoding="UTF-8"?>
 <ui version="4.0">
  <class>QmitkControlVisualizationPropertiesViewControls</class>
  <widget class="QWidget" name="QmitkControlVisualizationPropertiesViewControls">
   <property name="geometry">
    <rect>
     <x>0</x>
     <y>0</y>
     <width>567</width>
     <height>619</height>
    </rect>
   </property>
   <property name="sizePolicy">
    <sizepolicy hsizetype="Preferred" vsizetype="MinimumExpanding">
     <horstretch>0</horstretch>
     <verstretch>100</verstretch>
    </sizepolicy>
   </property>
   <property name="minimumSize">
    <size>
     <width>0</width>
     <height>0</height>
    </size>
   </property>
   <property name="windowTitle">
    <string>QmitkTemplate</string>
   </property>
   <layout class="QVBoxLayout" name="verticalLayout_4">
    <property name="leftMargin">
     <number>0</number>
    </property>
    <property name="topMargin">
     <number>0</number>
    </property>
    <property name="rightMargin">
     <number>0</number>
    </property>
    <property name="bottomMargin">
     <number>0</number>
    </property>
    <item>
     <widget class="QFrame" name="m_ImageControlsFrame">
      <property name="frameShape">
       <enum>QFrame::NoFrame</enum>
      </property>
      <property name="frameShadow">
       <enum>QFrame::Raised</enum>
      </property>
      <layout class="QVBoxLayout" name="verticalLayout">
       <property name="leftMargin">
        <number>0</number>
       </property>
       <property name="topMargin">
        <number>0</number>
       </property>
       <property name="rightMargin">
        <number>0</number>
       </property>
       <property name="bottomMargin">
        <number>0</number>
       </property>
       <item>
        <widget class="QFrame" name="frame_2">
         <property name="sizePolicy">
          <sizepolicy hsizetype="Expanding" vsizetype="Preferred">
           <horstretch>0</horstretch>
           <verstretch>0</verstretch>
          </sizepolicy>
         </property>
         <property name="frameShape">
          <enum>QFrame::NoFrame</enum>
         </property>
         <property name="frameShadow">
          <enum>QFrame::Raised</enum>
         </property>
         <layout class="QHBoxLayout" name="horizontalLayout_2">
          <property name="leftMargin">
           <number>0</number>
          </property>
          <property name="topMargin">
           <number>0</number>
          </property>
          <property name="rightMargin">
           <number>0</number>
          </property>
          <property name="bottomMargin">
           <number>0</number>
          </property>
          <item>
           <widget class="QToolButton" name="m_TSMenu">
            <property name="toolTip">
             <string>Multislice Projection</string>
            </property>
            <property name="statusTip">
             <string/>
            </property>
            <property name="whatsThis">
             <string/>
            </property>
            <property name="text">
             <string>MIP</string>
            </property>
            <property name="popupMode">
             <enum>QToolButton::MenuButtonPopup</enum>
            </property>
            <property name="arrowType">
             <enum>Qt::NoArrow</enum>
            </property>
           </widget>
          </item>
          <item>
           <widget class="QFrame" name="m_NumberGlyphsFrame">
            <property name="frameShape">
             <enum>QFrame::NoFrame</enum>
            </property>
            <property name="frameShadow">
             <enum>QFrame::Plain</enum>
            </property>
            <layout class="QHBoxLayout" name="horizontalLayout_6">
             <property name="leftMargin">
              <number>0</number>
             </property>
             <property name="topMargin">
              <number>0</number>
             </property>
             <property name="rightMargin">
              <number>0</number>
             </property>
             <property name="bottomMargin">
              <number>0</number>
             </property>
             <item>
              <widget class="QToolButton" name="m_VisibleOdfsON_T">
               <property name="toolTip">
                <string>Toggle visibility of ODF glyphs (axial)</string>
               </property>
               <property name="statusTip">
                <string/>
               </property>
               <property name="whatsThis">
                <string/>
               </property>
               <property name="text">
                <string/>
               </property>
               <property name="icon">
                <iconset resource="../../resources/QmitkDiffusionImaging.qrc">
                 <normaloff>:/QmitkDiffusionImaging/glyphsoff_T.png</normaloff>
                 <normalon>:/QmitkDiffusionImaging/glyphson_T.png</normalon>:/QmitkDiffusionImaging/glyphsoff_T.png</iconset>
               </property>
               <property name="checkable">
                <bool>true</bool>
               </property>
               <property name="checked">
                <bool>false</bool>
               </property>
              </widget>
             </item>
             <item>
              <widget class="QToolButton" name="m_VisibleOdfsON_S">
               <property name="toolTip">
                <string>Toggle visibility of ODF glyphs (sagittal)</string>
               </property>
               <property name="statusTip">
                <string/>
               </property>
               <property name="whatsThis">
                <string/>
               </property>
               <property name="text">
                <string/>
               </property>
               <property name="icon">
                <iconset resource="../../resources/QmitkDiffusionImaging.qrc">
                 <normaloff>:/QmitkDiffusionImaging/glyphsoff_S.png</normaloff>
                 <normalon>:/QmitkDiffusionImaging/glyphson_S.png</normalon>:/QmitkDiffusionImaging/glyphsoff_S.png</iconset>
               </property>
               <property name="checkable">
                <bool>true</bool>
               </property>
               <property name="checked">
                <bool>false</bool>
               </property>
              </widget>
             </item>
             <item>
              <widget class="QToolButton" name="m_VisibleOdfsON_C">
               <property name="toolTip">
                <string>Toggle visibility of ODF glyphs (coronal)</string>
               </property>
               <property name="statusTip">
                <string/>
               </property>
               <property name="whatsThis">
                <string/>
               </property>
               <property name="text">
                <string/>
               </property>
               <property name="icon">
                <iconset resource="../../resources/QmitkDiffusionImaging.qrc">
                 <normaloff>:/QmitkDiffusionImaging/glyphsoff_C.png</normaloff>
                 <normalon>:/QmitkDiffusionImaging/glyphson_C.png</normalon>:/QmitkDiffusionImaging/glyphsoff_C.png</iconset>
               </property>
               <property name="checkable">
                <bool>true</bool>
               </property>
               <property name="checked">
                <bool>false</bool>
               </property>
              </widget>
             </item>
             <item>
              <widget class="QLabel" name="label_glyphs">
               <property name="text">
                <string>#Glyphs</string>
               </property>
              </widget>
             </item>
             <item>
              <widget class="QSpinBox" name="m_ShowMaxNumber">
               <property name="maximum">
                <number>9999</number>
               </property>
              </widget>
             </item>
             <item>
              <spacer name="horizontalSpacer">
               <property name="orientation">
                <enum>Qt::Horizontal</enum>
               </property>
               <property name="sizeHint" stdset="0">
                <size>
                 <width>20</width>
                 <height>20</height>
                </size>
               </property>
              </spacer>
             </item>
            </layout>
           </widget>
          </item>
         </layout>
        </widget>
       </item>
       <item>
        <widget class="QFrame" name="m_GlyphFrame">
         <property name="frameShape">
          <enum>QFrame::NoFrame</enum>
         </property>
         <property name="frameShadow">
          <enum>QFrame::Raised</enum>
         </property>
         <layout class="QVBoxLayout" name="verticalLayout_2">
          <property name="spacing">
           <number>0</number>
          </property>
          <property name="leftMargin">
           <number>0</number>
          </property>
          <property name="topMargin">
           <number>0</number>
          </property>
          <property name="rightMargin">
           <number>0</number>
          </property>
          <property name="bottomMargin">
           <number>0</number>
          </property>
          <item>
           <widget class="QFrame" name="m_NormalizationScalingFrame">
            <property name="frameShape">
             <enum>QFrame::NoFrame</enum>
            </property>
            <property name="frameShadow">
             <enum>QFrame::Raised</enum>
            </property>
            <layout class="QGridLayout" name="gridLayout">
             <property name="leftMargin">
              <number>0</number>
             </property>
             <property name="topMargin">
              <number>0</number>
             </property>
             <property name="rightMargin">
              <number>0</number>
             </property>
             <property name="bottomMargin">
              <number>0</number>
             </property>
             <property name="horizontalSpacing">
              <number>6</number>
             </property>
             <property name="verticalSpacing">
              <number>0</number>
             </property>
             <item row="1" column="1">
              <widget class="QFrame" name="m_ScalingFrame">
               <property name="frameShape">
                <enum>QFrame::NoFrame</enum>
               </property>
               <property name="frameShadow">
                <enum>QFrame::Plain</enum>
               </property>
               <layout class="QHBoxLayout" name="horizontalLayout_3">
                <property name="leftMargin">
                 <number>0</number>
                </property>
                <property name="topMargin">
                 <number>0</number>
                </property>
                <property name="rightMargin">
                 <number>0</number>
                </property>
                <property name="bottomMargin">
                 <number>0</number>
                </property>
                <item>
                 <widget class="QComboBox" name="m_AdditionalScaling">
                  <property name="frame">
                   <bool>false</bool>
                  </property>
                  <item>
                   <property name="text">
                    <string>None</string>
                   </property>
                  </item>
                  <item>
                   <property name="text">
                    <string>By GFA</string>
                   </property>
                  </item>
                  <item>
                   <property name="text">
                    <string>By ASR</string>
                   </property>
                  </item>
                 </widget>
                </item>
                <item>
                 <widget class="QLabel" name="label">
                  <property name="text">
                   <string>*</string>
                  </property>
                 </widget>
                </item>
                <item>
                 <widget class="QDoubleSpinBox" name="m_ScalingFactor">
                  <property name="toolTip">
                   <string>Additional scaling factor</string>
                  </property>
                  <property name="decimals">
                   <number>3</number>
                  </property>
                  <property name="maximum">
                   <double>999999999.000000000000000</double>
                  </property>
                  <property name="singleStep">
                   <double>0.100000000000000</double>
                  </property>
                  <property name="value">
                   <double>1.000000000000000</double>
                  </property>
                 </widget>
                </item>
               </layout>
              </widget>
             </item>
             <item row="0" column="1">
              <widget class="QCheckBox" name="m_ScalingCheckbox">
               <property name="text">
                <string>Scaling</string>
               </property>
              </widget>
             </item>
             <item row="1" column="0">
              <widget class="QFrame" name="m_NormalizationFrame">
               <property name="frameShape">
                <enum>QFrame::NoFrame</enum>
               </property>
               <property name="frameShadow">
                <enum>QFrame::Plain</enum>
               </property>
               <layout class="QHBoxLayout" name="horizontalLayout_5">
                <property name="spacing">
                 <number>0</number>
                </property>
                <property name="leftMargin">
                 <number>0</number>
                </property>
                <property name="topMargin">
                 <number>0</number>
                </property>
                <property name="rightMargin">
                 <number>0</number>
                </property>
                <property name="bottomMargin">
                 <number>0</number>
                </property>
               </layout>
              </widget>
             </item>
             <item row="0" column="0">
              <widget class="QComboBox" name="m_NormalizationDropdown">
               <property name="toolTip">
                <string>ODF normalization</string>
               </property>
               <property name="frame">
                <bool>false</bool>
               </property>
               <item>
                <property name="text">
                 <string>Min-Max</string>
                </property>
               </item>
               <item>
                <property name="text">
                 <string>Max</string>
                </property>
               </item>
               <item>
                <property name="text">
                 <string>None</string>
                </property>
               </item>
              </widget>
             </item>
            </layout>
           </widget>
          </item>
         </layout>
        </widget>
       </item>
      </layout>
     </widget>
    </item>
    <item>
     <widget class="QFrame" name="m_BundleControlsFrame">
      <property name="frameShape">
       <enum>QFrame::NoFrame</enum>
      </property>
      <property name="frameShadow">
       <enum>QFrame::Raised</enum>
      </property>
      <layout class="QVBoxLayout" name="verticalLayout_3">
       <property name="leftMargin">
        <number>0</number>
       </property>
       <property name="topMargin">
        <number>0</number>
       </property>
       <property name="rightMargin">
        <number>0</number>
       </property>
       <property name="bottomMargin">
        <number>0</number>
       </property>
       <item>
        <widget class="QFrame" name="frame_5">
         <property name="frameShape">
          <enum>QFrame::NoFrame</enum>
         </property>
         <property name="frameShadow">
          <enum>QFrame::Raised</enum>
         </property>
         <layout class="QHBoxLayout" name="horizontalLayout_11">
          <property name="leftMargin">
           <number>0</number>
          </property>
          <property name="topMargin">
           <number>0</number>
          </property>
          <property name="rightMargin">
           <number>0</number>
          </property>
          <property name="bottomMargin">
           <number>0</number>
          </property>
          <item>
           <widget class="QToolButton" name="m_ResetColoring">
            <property name="toolTip">
             <string>Reset to Default Coloring</string>
            </property>
            <property name="text">
             <string/>
            </property>
            <property name="icon">
             <iconset resource="../../resources/QmitkDiffusionImaging.qrc">
              <normaloff>:/QmitkDiffusionImaging/reset.png</normaloff>:/QmitkDiffusionImaging/reset.png</iconset>
            </property>
           </widget>
          </item>
          <item>
           <widget class="QToolButton" name="m_Crosshair">
            <property name="toolTip">
             <string>Position Crosshair by 3D-Click</string>
            </property>
            <property name="statusTip">
             <string/>
            </property>
            <property name="text">
             <string/>
            </property>
            <property name="icon">
             <iconset resource="../../resources/QmitkDiffusionImaging.qrc">
              <normaloff>:/QmitkDiffusionImaging/crosshair.png</normaloff>:/QmitkDiffusionImaging/crosshair.png</iconset>
            </property>
            <property name="checkable">
             <bool>true</bool>
            </property>
            <property name="checked">
             <bool>false</bool>
            </property>
           </widget>
          </item>
          <item>
           <widget class="QToolButton" name="m_FiberFading2D">
            <property name="toolTip">
             <string>2D Fiberfading on/off</string>
            </property>
            <property name="text">
             <string/>
            </property>
           </widget>
          </item>
          <item>
           <spacer name="horizontalSpacer_2">
            <property name="orientation">
             <enum>Qt::Horizontal</enum>
            </property>
            <property name="sizeHint" stdset="0">
             <size>
              <width>40</width>
              <height>20</height>
             </size>
            </property>
           </spacer>
          </item>
         </layout>
        </widget>
       </item>
       <item>
        <widget class="QFrame" name="frame_6">
         <property name="frameShape">
          <enum>QFrame::NoFrame</enum>
         </property>
         <property name="frameShadow">
          <enum>QFrame::Raised</enum>
         </property>
         <layout class="QHBoxLayout" name="horizontalLayout_10">
          <property name="leftMargin">
           <number>0</number>
          </property>
          <property name="topMargin">
           <number>0</number>
          </property>
          <property name="rightMargin">
           <number>0</number>
          </property>
          <property name="bottomMargin">
           <number>0</number>
          </property>
          <item>
           <widget class="QLabel" name="label_5">
            <property name="text">
             <string>  2D Clipping</string>
            </property>
           </widget>
          </item>
          <item>
           <widget class="QSlider" name="m_FiberThicknessSlider">
            <property name="maximum">
             <number>100</number>
            </property>
            <property name="pageStep">
             <number>10</number>
            </property>
            <property name="value">
             <number>10</number>
            </property>
            <property name="sliderPosition">
             <number>10</number>
            </property>
            <property name="orientation">
             <enum>Qt::Horizontal</enum>
            </property>
           </widget>
          </item>
          <item>
           <widget class="QLabel" name="label_range">
            <property name="minimumSize">
             <size>
              <width>90</width>
              <height>0</height>
             </size>
            </property>
            <property name="maximumSize">
             <size>
              <width>10000</width>
              <height>16777215</height>
             </size>
            </property>
            <property name="text">
             <string>Range</string>
            </property>
           </widget>
          </item>
         </layout>
        </widget>
       </item>
       <item>
        <widget class="QFrame" name="frame_linewidth">
         <property name="frameShape">
          <enum>QFrame::NoFrame</enum>
         </property>
         <property name="frameShadow">
          <enum>QFrame::Raised</enum>
         </property>
         <layout class="QGridLayout" name="gridLayout_2">
          <property name="leftMargin">
           <number>0</number>
          </property>
          <property name="topMargin">
           <number>0</number>
          </property>
          <property name="rightMargin">
           <number>0</number>
          </property>
          <property name="bottomMargin">
           <number>0</number>
          </property>
-         <item row="1" column="0">
-          <widget class="QLabel" name="label_6">
-           <property name="text">
-            <string>Tube Width</string>
+         <item row="0" column="1">
+          <widget class="QSpinBox" name="m_LineWidth">
+           <property name="minimum">
+            <number>1</number>
+           </property>
+           <property name="maximum">
+            <number>10</number>
            </property>
           </widget>
          </item>
          <item row="0" column="0">
           <widget class="QLabel" name="label_7">
            <property name="text">
             <string>Line Width</string>
            </property>
           </widget>
          </item>
-         <item row="0" column="1">
-          <widget class="QSpinBox" name="m_LineWidth">
-           <property name="minimum">
-            <number>1</number>
-           </property>
-           <property name="maximum">
-            <number>10</number>
+         <item row="1" column="0">
+          <widget class="QLabel" name="label_8">
+           <property name="text">
+            <string>Tube Radius</string>
            </property>
           </widget>
          </item>
          <item row="1" column="1">
           <widget class="QDoubleSpinBox" name="m_TubeWidth">
-           <property name="toolTip">
-            <string>Fiber tube radius in mm. If &gt; 0, fibers are rendered as tubes in 3D.</string>
-           </property>
            <property name="decimals">
             <number>4</number>
            </property>
            <property name="singleStep">
             <double>0.100000000000000</double>
            </property>
           </widget>
          </item>
         </layout>
        </widget>
       </item>
      </layout>
     </widget>
    </item>
    <item>
     <widget class="QLabel" name="m_lblRotatedPlanesWarning">
      <property name="font">
       <font>
        <weight>50</weight>
        <italic>false</italic>
        <bold>false</bold>
       </font>
      </property>
      <property name="text">
       <string>&lt;!DOCTYPE HTML PUBLIC &quot;-//W3C//DTD HTML 4.0//EN&quot; &quot;http://www.w3.org/TR/REC-html40/strict.dtd&quot;&gt;
 &lt;html&gt;&lt;head&gt;&lt;meta name=&quot;qrichtext&quot; content=&quot;1&quot; /&gt;&lt;style type=&quot;text/css&quot;&gt;
 p, li { white-space: pre-wrap; }
 &lt;/style&gt;&lt;/head&gt;&lt;body style=&quot; font-family:'Ubuntu'; font-size:11pt; font-weight:400; font-style:normal;&quot;&gt;
 &lt;p align=&quot;center&quot; style=&quot; margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; -qt-block-indent:0; text-indent:0px;&quot;&gt;&lt;span style=&quot; color:#ff0000;&quot;&gt;One or more slices are rotated.  ODF Visualisation is not possible in rotated planes. Use 'Reinit' on the image node to reset. &lt;/span&gt;&lt;/p&gt;&lt;/body&gt;&lt;/html&gt;</string>
      </property>
      <property name="textFormat">
       <enum>Qt::AutoText</enum>
      </property>
      <property name="wordWrap">
       <bool>true</bool>
      </property>
     </widget>
    </item>
    <item>
     <spacer name="verticalSpacer">
      <property name="orientation">
       <enum>Qt::Vertical</enum>
      </property>
      <property name="sizeHint" stdset="0">
       <size>
        <width>20</width>
        <height>40</height>
       </size>
      </property>
     </spacer>
    </item>
   </layout>
  </widget>
  <layoutdefault spacing="6" margin="11"/>
  <includes>
   <include location="local">QmitkDataStorageComboBox.h</include>
  </includes>
  <resources>
   <include location="../../resources/QmitkDiffusionImaging.qrc"/>
  </resources>
  <connections/>
 </ui>
diff --git a/Plugins/org.mitk.gui.qt.diffusionimaging/src/internal/QmitkFiberProcessingView.cpp b/Plugins/org.mitk.gui.qt.diffusionimaging/src/internal/QmitkFiberProcessingView.cpp
index 94e15c8103..a95f56d5a9 100644
--- a/Plugins/org.mitk.gui.qt.diffusionimaging/src/internal/QmitkFiberProcessingView.cpp
+++ b/Plugins/org.mitk.gui.qt.diffusionimaging/src/internal/QmitkFiberProcessingView.cpp
@@ -1,1359 +1,1361 @@
 /*===================================================================
 
 The Medical Imaging Interaction Toolkit (MITK)
 
 Copyright (c) German Cancer Research Center,
 Division of Medical and Biological Informatics.
 All rights reserved.
 
 This software is distributed WITHOUT ANY WARRANTY; without
 even the implied warranty of MERCHANTABILITY or FITNESS FOR
 A PARTICULAR PURPOSE.
 
 See LICENSE.txt or http://www.mitk.org for details.
 
 ===================================================================*/
 
 
 // Blueberry
 #include <berryISelectionService.h>
 #include <berryIWorkbenchWindow.h>
 
 // Qmitk
 #include "QmitkFiberProcessingView.h"
 #include <QmitkStdMultiWidget.h>
 
 // Qt
 #include <QMessageBox>
 
 // MITK
 #include <mitkNodePredicateProperty.h>
 #include <mitkImageCast.h>
 #include <mitkPointSet.h>
 #include <mitkPlanarCircle.h>
 #include <mitkPlanarPolygon.h>
 #include <mitkPlanarRectangle.h>
 #include <mitkPlanarFigureInteractor.h>
 #include <mitkGlobalInteraction.h>
 #include <mitkImageAccessByItk.h>
 #include <mitkDataNodeObject.h>
 #include <mitkTensorImage.h>
 #include "usModuleRegistry.h"
 #include <itkFiberCurvatureFilter.h>
 
 #include "mitkNodePredicateDataType.h"
 #include <mitkNodePredicateProperty.h>
 #include <mitkNodePredicateAnd.h>
 #include <mitkNodePredicateNot.h>
 #include <mitkNodePredicateOr.h>
 
 // ITK
 #include <itkResampleImageFilter.h>
 #include <itkGaussianInterpolateImageFunction.h>
 #include <itkImageRegionIteratorWithIndex.h>
 #include <itkTractsToFiberEndingsImageFilter.h>
 #include <itkTractDensityImageFilter.h>
 #include <itkImageRegion.h>
 #include <itkTractsToRgbaImageFilter.h>
 
 #define _USE_MATH_DEFINES
 #include <math.h>
 
 
 const std::string QmitkFiberProcessingView::VIEW_ID = "org.mitk.views.fiberprocessing";
 const std::string id_DataManager = "org.mitk.views.datamanager";
 using namespace mitk;
 
 QmitkFiberProcessingView::QmitkFiberProcessingView()
     : QmitkFunctionality()
     , m_Controls( 0 )
     , m_MultiWidget( NULL )
     , m_CircleCounter(0)
     , m_PolygonCounter(0)
     , m_UpsamplingFactor(1)
 {
 
 }
 
 // Destructor
 QmitkFiberProcessingView::~QmitkFiberProcessingView()
 {
 
 }
 
 void QmitkFiberProcessingView::CreateQtPartControl( QWidget *parent )
 {
     // build up qt view, unless already done
     if ( !m_Controls )
     {
         // create GUI widgets from the Qt Designer's .ui file
         m_Controls = new Ui::QmitkFiberProcessingViewControls;
         m_Controls->setupUi( parent );
 
         connect( m_Controls->m_CircleButton, SIGNAL( clicked() ), this, SLOT( OnDrawCircle() ) );
         connect( m_Controls->m_PolygonButton, SIGNAL( clicked() ), this, SLOT( OnDrawPolygon() ) );
         connect(m_Controls->PFCompoANDButton, SIGNAL(clicked()), this, SLOT(GenerateAndComposite()) );
         connect(m_Controls->PFCompoORButton, SIGNAL(clicked()), this, SLOT(GenerateOrComposite()) );
         connect(m_Controls->PFCompoNOTButton, SIGNAL(clicked()), this, SLOT(GenerateNotComposite()) );
         connect(m_Controls->m_GenerateRoiImage, SIGNAL(clicked()), this, SLOT(GenerateRoiImage()) );
 
         connect(m_Controls->m_JoinBundles, SIGNAL(clicked()), this, SLOT(JoinBundles()) );
         connect(m_Controls->m_SubstractBundles, SIGNAL(clicked()), this, SLOT(SubstractBundles()) );
 
         connect(m_Controls->m_ExtractFibersButton, SIGNAL(clicked()), this, SLOT(Extract()));
         connect(m_Controls->m_RemoveButton, SIGNAL(clicked()), this, SLOT(Remove()));
         connect(m_Controls->m_ModifyButton, SIGNAL(clicked()), this, SLOT(Modify()));
 
         connect(m_Controls->m_ExtractionMethodBox, SIGNAL(currentIndexChanged(int)), this, SLOT(UpdateGui()));
         connect(m_Controls->m_RemovalMethodBox, SIGNAL(currentIndexChanged(int)), this, SLOT(UpdateGui()));
         connect(m_Controls->m_ModificationMethodBox, SIGNAL(currentIndexChanged(int)), this, SLOT(UpdateGui()));
 
         m_Controls->m_ColorMapBox->SetDataStorage(this->GetDataStorage());
         mitk::TNodePredicateDataType<mitk::Image>::Pointer isMitkImage = mitk::TNodePredicateDataType<mitk::Image>::New();
         mitk::NodePredicateDataType::Pointer isDwi = mitk::NodePredicateDataType::New("DiffusionImage");
         mitk::NodePredicateDataType::Pointer isDti = mitk::NodePredicateDataType::New("TensorImage");
         mitk::NodePredicateDataType::Pointer isQbi = mitk::NodePredicateDataType::New("QBallImage");
         mitk::NodePredicateOr::Pointer isDiffusionImage = mitk::NodePredicateOr::New(isDwi, isDti);
         isDiffusionImage = mitk::NodePredicateOr::New(isDiffusionImage, isQbi);
         mitk::NodePredicateNot::Pointer noDiffusionImage = mitk::NodePredicateNot::New(isDiffusionImage);
         mitk::NodePredicateAnd::Pointer finalPredicate = mitk::NodePredicateAnd::New(isMitkImage, noDiffusionImage);
         m_Controls->m_ColorMapBox->SetPredicate(finalPredicate);
     }
 
     UpdateGui();
 }
 
 void QmitkFiberProcessingView::Modify()
 {
     switch (m_Controls->m_ModificationMethodBox->currentIndex())
     {
     case 0:
     {
         ResampleSelectedBundles();
         break;
     }
     case 1:
     {
         CompressSelectedBundles();
         break;
     }
     case 2:
     {
         DoImageColorCoding();
         break;
     }
     case 3:
     {
         MirrorFibers();
         break;
     }
     case 4:
     {
         WeightFibers();
         break;
     }
     case 5:
     {
         DoCurvatureColorCoding();
         break;
     }
     }
 }
 
 void QmitkFiberProcessingView::WeightFibers()
 {
     float weight = this->m_Controls->m_BundleWeightBox->value();
     for (int i=0; i<m_SelectedFB.size(); i++)
     {
         mitk::FiberBundle::Pointer fib = dynamic_cast<mitk::FiberBundle*>(m_SelectedFB.at(i)->GetData());
         fib->SetFiberWeights(weight);
     }
 
 }
 
 void QmitkFiberProcessingView::Remove()
 {
     switch (m_Controls->m_RemovalMethodBox->currentIndex())
     {
     case 0:
     {
         RemoveDir();
         break;
     }
     case 1:
     {
         PruneBundle();
         break;
     }
     case 2:
     {
         ApplyCurvatureThreshold();
         break;
     }
     case 3:
     {
         RemoveWithMask(false);
         break;
     }
     case 4:
     {
         RemoveWithMask(true);
         break;
     }
     }
 }
 
 void QmitkFiberProcessingView::Extract()
 {
     switch (m_Controls->m_ExtractionMethodBox->currentIndex())
     {
     case 0:
     {
         ExtractWithPlanarFigure();
         break;
     }
     case 1:
     {
         switch (m_Controls->m_ExtractionBoxMask->currentIndex())
         {
         {
         case 0:
             ExtractWithMask(true, false);
             break;
         }
         {
         case 1:
             ExtractWithMask(true, true);
             break;
         }
         {
         case 2:
             ExtractWithMask(false, false);
             break;
         }
         {
         case 3:
             ExtractWithMask(false, true);
             break;
         }
         }
         break;
     }
     }
 }
 
 void QmitkFiberProcessingView::PruneBundle()
 {
     int minLength = this->m_Controls->m_PruneFibersMinBox->value();
     int maxLength = this->m_Controls->m_PruneFibersMaxBox->value();
     for (int i=0; i<m_SelectedFB.size(); i++)
     {
         mitk::FiberBundle::Pointer fib = dynamic_cast<mitk::FiberBundle*>(m_SelectedFB.at(i)->GetData());
         if (!fib->RemoveShortFibers(minLength))
             QMessageBox::information(NULL, "No output generated:", "The resulting fiber bundle contains no fibers.");
         else if (!fib->RemoveLongFibers(maxLength))
             QMessageBox::information(NULL, "No output generated:", "The resulting fiber bundle contains no fibers.");
     }
     RenderingManager::GetInstance()->RequestUpdateAll();
 }
 
 void QmitkFiberProcessingView::ApplyCurvatureThreshold()
 {
     int angle = this->m_Controls->m_CurvSpinBox->value();
     int dist = this->m_Controls->m_CurvDistanceSpinBox->value();
     std::vector< DataNode::Pointer > nodes = m_SelectedFB;
     for (int i=0; i<nodes.size(); i++)
     {
         mitk::FiberBundle::Pointer fib = dynamic_cast<mitk::FiberBundle*>(nodes.at(i)->GetData());
 
         itk::FiberCurvatureFilter::Pointer filter = itk::FiberCurvatureFilter::New();
         filter->SetInputFiberBundle(fib);
         filter->SetAngularDeviation(angle);
         filter->SetDistance(dist);
         filter->SetRemoveFibers(m_Controls->m_RemoveCurvedFibersBox->isChecked());
         filter->Update();
         mitk::FiberBundle::Pointer newFib = filter->GetOutputFiberBundle();
         if (newFib->GetNumFibers()>0)
         {
             nodes.at(i)->SetVisibility(false);
             DataNode::Pointer newNode = DataNode::New();
             newNode->SetData(newFib);
             newNode->SetName(nodes.at(i)->GetName()+"_Curvature");
             GetDefaultDataStorage()->Add(newNode, nodes.at(i));
         }
         else
             QMessageBox::information(NULL, "No output generated:", "The resulting fiber bundle contains no fibers.");
 //        if (!fib->ApplyCurvatureThreshold(mm, this->m_Controls->m_RemoveCurvedFibersBox->isChecked()))
 //            QMessageBox::information(NULL, "No output generated:", "The resulting fiber bundle contains no fibers.");
     }
     RenderingManager::GetInstance()->RequestUpdateAll();
 }
 
 void QmitkFiberProcessingView::RemoveDir()
 {
     for (unsigned int i=0; i<m_SelectedFB.size(); i++)
     {
         mitk::FiberBundle::Pointer fib = dynamic_cast<mitk::FiberBundle*>(m_SelectedFB.at(i)->GetData());
         vnl_vector_fixed<double,3> dir;
         dir[0] = m_Controls->m_ExtractDirX->value();
         dir[1] = m_Controls->m_ExtractDirY->value();
         dir[2] = m_Controls->m_ExtractDirZ->value();
         fib->RemoveDir(dir,cos((float)m_Controls->m_ExtractAngle->value()*M_PI/180));
     }
     RenderingManager::GetInstance()->RequestUpdateAll();
 }
 
 void QmitkFiberProcessingView::RemoveWithMask(bool removeInside)
 {
     if (m_MaskImageNode.IsNull())
         return;
 
     mitk::Image::Pointer mitkMask = dynamic_cast<mitk::Image*>(m_MaskImageNode->GetData());
     for (unsigned int i=0; i<m_SelectedFB.size(); i++)
     {
         mitk::FiberBundle::Pointer fib = dynamic_cast<mitk::FiberBundle*>(m_SelectedFB.at(i)->GetData());
         QString name(m_SelectedFB.at(i)->GetName().c_str());
 
         itkUCharImageType::Pointer mask = itkUCharImageType::New();
         mitk::CastToItkImage(mitkMask, mask);
         mitk::FiberBundle::Pointer newFib = fib->RemoveFibersOutside(mask, removeInside);
         if (newFib->GetNumFibers()<=0)
         {
             QMessageBox::information(NULL, "No output generated:", "The resulting fiber bundle contains no fibers.");
             continue;
         }
         DataNode::Pointer newNode = DataNode::New();
         newNode->SetData(newFib);
         if (removeInside)
             name += "_Inside";
         else
             name += "_Outside";
         newNode->SetName(name.toStdString());
         GetDefaultDataStorage()->Add(newNode);
         m_SelectedFB.at(i)->SetVisibility(false);
     }
 }
 
 void QmitkFiberProcessingView::ExtractWithMask(bool onlyEnds, bool invert)
 {
     if (m_MaskImageNode.IsNull())
         return;
 
     mitk::Image::Pointer mitkMask = dynamic_cast<mitk::Image*>(m_MaskImageNode->GetData());
     for (unsigned int i=0; i<m_SelectedFB.size(); i++)
     {
         mitk::FiberBundle::Pointer fib = dynamic_cast<mitk::FiberBundle*>(m_SelectedFB.at(i)->GetData());
         QString name(m_SelectedFB.at(i)->GetName().c_str());
 
         itkUCharImageType::Pointer mask = itkUCharImageType::New();
         mitk::CastToItkImage(mitkMask, mask);
-        mitk::FiberBundle::Pointer newFib = fib->ExtractFiberSubset(mask, onlyEnds, invert);
+        mitk::FiberBundle::Pointer newFib = fib->ExtractFiberSubset(mask, !onlyEnds, invert);
         if (newFib->GetNumFibers()<=0)
         {
             QMessageBox::information(NULL, "No output generated:", "The resulting fiber bundle contains no fibers.");
             continue;
         }
 
         DataNode::Pointer newNode = DataNode::New();
         newNode->SetData(newFib);
 
         if (invert)
         {
             name += "_not";
 
             if (onlyEnds)
                 name += "-ending-in-mask";
             else
                 name += "-passing-mask";
         }
         else
         {
             if (onlyEnds)
                 name += "_ending-in-mask";
             else
                 name += "_passing-mask";
         }
 
         newNode->SetName(name.toStdString());
         GetDefaultDataStorage()->Add(newNode);
         m_SelectedFB.at(i)->SetVisibility(false);
     }
 }
 
 void QmitkFiberProcessingView::GenerateRoiImage()
 {
     if (m_SelectedPF.empty())
         return;
 
     mitk::BaseGeometry::Pointer geometry;
     if (!m_SelectedFB.empty())
     {
         mitk::FiberBundle::Pointer fib = dynamic_cast<mitk::FiberBundle*>(m_SelectedFB.front()->GetData());
         geometry = fib->GetGeometry();
     }
     else if (m_SelectedImage)
         geometry = m_SelectedImage->GetGeometry();
     else
         return;
 
     itk::Vector<double,3> spacing = geometry->GetSpacing();
     spacing /= m_UpsamplingFactor;
 
     mitk::Point3D newOrigin = geometry->GetOrigin();
     mitk::Geometry3D::BoundsArrayType bounds = geometry->GetBounds();
     newOrigin[0] += bounds.GetElement(0);
     newOrigin[1] += bounds.GetElement(2);
     newOrigin[2] += bounds.GetElement(4);
 
     itk::Matrix<double, 3, 3> direction;
     itk::ImageRegion<3> imageRegion;
     for (int i=0; i<3; i++)
         for (int j=0; j<3; j++)
             direction[j][i] = geometry->GetMatrixColumn(i)[j]/spacing[j];
     imageRegion.SetSize(0, geometry->GetExtent(0)*m_UpsamplingFactor);
     imageRegion.SetSize(1, geometry->GetExtent(1)*m_UpsamplingFactor);
     imageRegion.SetSize(2, geometry->GetExtent(2)*m_UpsamplingFactor);
 
     m_PlanarFigureImage = itkUCharImageType::New();
     m_PlanarFigureImage->SetSpacing( spacing );   // Set the image spacing
     m_PlanarFigureImage->SetOrigin( newOrigin );     // Set the image origin
     m_PlanarFigureImage->SetDirection( direction );  // Set the image direction
     m_PlanarFigureImage->SetRegions( imageRegion );
     m_PlanarFigureImage->Allocate();
     m_PlanarFigureImage->FillBuffer( 0 );
 
     Image::Pointer tmpImage = Image::New();
     tmpImage->InitializeByItk(m_PlanarFigureImage.GetPointer());
     tmpImage->SetVolume(m_PlanarFigureImage->GetBufferPointer());
 
     std::string name = m_SelectedPF.at(0)->GetName();
     WritePfToImage(m_SelectedPF.at(0), tmpImage);
     for (unsigned int i=1; i<m_SelectedPF.size(); i++)
     {
         name += "+";
         name += m_SelectedPF.at(i)->GetName();
         WritePfToImage(m_SelectedPF.at(i), tmpImage);
     }
 
     DataNode::Pointer node = DataNode::New();
     tmpImage = Image::New();
     tmpImage->InitializeByItk(m_PlanarFigureImage.GetPointer());
     tmpImage->SetVolume(m_PlanarFigureImage->GetBufferPointer());
     node->SetData(tmpImage);
     node->SetName(name);
     this->GetDefaultDataStorage()->Add(node);
 }
 
 void QmitkFiberProcessingView::WritePfToImage(mitk::DataNode::Pointer node, mitk::Image* image)
 {
     if (dynamic_cast<mitk::PlanarFigure*>(node->GetData()))
     {
         m_PlanarFigure = dynamic_cast<mitk::PlanarFigure*>(node->GetData());
         AccessFixedDimensionByItk_2(
                     image,
                     InternalReorientImagePlane, 3,
                     m_PlanarFigure->GetGeometry(), -1);
 
         AccessFixedDimensionByItk_2(
                     m_InternalImage,
                     InternalCalculateMaskFromPlanarFigure,
                     3, 2, node->GetName() );
     }
     else if (dynamic_cast<mitk::PlanarFigureComposite*>(node->GetData()))
     {
         DataStorage::SetOfObjects::ConstPointer children = GetDataStorage()->GetDerivations(node);
         for (int j=0; j<children->size(); j++)
         {
             WritePfToImage(children->ElementAt(j), image);
         }
     }
 }
 
 template < typename TPixel, unsigned int VImageDimension >
 void QmitkFiberProcessingView::InternalReorientImagePlane( const itk::Image< TPixel, VImageDimension > *image, mitk::BaseGeometry* planegeo3D, int additionalIndex )
 {
     typedef itk::Image< TPixel, VImageDimension > ImageType;
     typedef itk::Image< float, VImageDimension > FloatImageType;
 
     typedef itk::ResampleImageFilter<ImageType, FloatImageType, double> ResamplerType;
     typename ResamplerType::Pointer resampler = ResamplerType::New();
 
     mitk::PlaneGeometry* planegeo = dynamic_cast<mitk::PlaneGeometry*>(planegeo3D);
 
     float upsamp = m_UpsamplingFactor;
     float gausssigma = 0.5;
 
     // Spacing
     typename ResamplerType::SpacingType spacing = planegeo->GetSpacing();
     spacing[0] = image->GetSpacing()[0] / upsamp;
     spacing[1] = image->GetSpacing()[1] / upsamp;
     spacing[2] = image->GetSpacing()[2];
     resampler->SetOutputSpacing( spacing );
 
     // Size
     typename ResamplerType::SizeType size;
     size[0] = planegeo->GetExtentInMM(0) / spacing[0];
     size[1] = planegeo->GetExtentInMM(1) / spacing[1];
     size[2] = 1;
     resampler->SetSize( size );
 
     // Origin
     typename mitk::Point3D orig = planegeo->GetOrigin();
     typename mitk::Point3D corrorig;
     planegeo3D->WorldToIndex(orig,corrorig);
     corrorig[0] += 0.5/upsamp;
     corrorig[1] += 0.5/upsamp;
     corrorig[2] += 0;
     planegeo3D->IndexToWorld(corrorig,corrorig);
     resampler->SetOutputOrigin(corrorig );
 
     // Direction
     typename ResamplerType::DirectionType direction;
     typename mitk::AffineTransform3D::MatrixType matrix = planegeo->GetIndexToWorldTransform()->GetMatrix();
     for(int c=0; c<matrix.ColumnDimensions; c++)
     {
         double sum = 0;
         for(int r=0; r<matrix.RowDimensions; r++)
             sum += matrix(r,c)*matrix(r,c);
         for(int r=0; r<matrix.RowDimensions; r++)
             direction(r,c) = matrix(r,c)/sqrt(sum);
     }
     resampler->SetOutputDirection( direction );
 
     // Gaussian interpolation
     if(gausssigma != 0)
     {
         double sigma[3];
         for( unsigned int d = 0; d < 3; d++ )
             sigma[d] = gausssigma * image->GetSpacing()[d];
         double alpha = 2.0;
         typedef itk::GaussianInterpolateImageFunction<ImageType, double> GaussianInterpolatorType;
         typename GaussianInterpolatorType::Pointer interpolator = GaussianInterpolatorType::New();
         interpolator->SetInputImage( image );
         interpolator->SetParameters( sigma, alpha );
         resampler->SetInterpolator( interpolator );
     }
     else
     {
         typedef typename itk::LinearInterpolateImageFunction<ImageType, double> InterpolatorType;
         typename InterpolatorType::Pointer interpolator = InterpolatorType::New();
         interpolator->SetInputImage( image );
         resampler->SetInterpolator( interpolator );
     }
 
     resampler->SetInput( image );
     resampler->SetDefaultPixelValue(0);
     resampler->Update();
 
     if(additionalIndex < 0)
     {
         this->m_InternalImage = mitk::Image::New();
         this->m_InternalImage->InitializeByItk( resampler->GetOutput() );
         this->m_InternalImage->SetVolume( resampler->GetOutput()->GetBufferPointer() );
     }
 }
 
 template < typename TPixel, unsigned int VImageDimension >
 void QmitkFiberProcessingView::InternalCalculateMaskFromPlanarFigure( itk::Image< TPixel, VImageDimension > *image, unsigned int axis, std::string )
 {
     typedef itk::Image< TPixel, VImageDimension > ImageType;
     typedef itk::CastImageFilter< ImageType, itkUCharImageType > CastFilterType;
 
     // Generate mask image as new image with same header as input image and
     // initialize with "1".
     itkUCharImageType::Pointer newMaskImage = itkUCharImageType::New();
     newMaskImage->SetSpacing( image->GetSpacing() );   // Set the image spacing
     newMaskImage->SetOrigin( image->GetOrigin() );     // Set the image origin
     newMaskImage->SetDirection( image->GetDirection() );  // Set the image direction
     newMaskImage->SetRegions( image->GetLargestPossibleRegion() );
     newMaskImage->Allocate();
     newMaskImage->FillBuffer( 1 );
 
     // Generate VTK polygon from (closed) PlanarFigure polyline
     // (The polyline points are shifted by -0.5 in z-direction to make sure
     // that the extrusion filter, which afterwards elevates all points by +0.5
     // in z-direction, creates a 3D object which is cut by the the plane z=0)
     const PlaneGeometry *planarFigurePlaneGeometry = m_PlanarFigure->GetPlaneGeometry();
     const PlanarFigure::PolyLineType planarFigurePolyline = m_PlanarFigure->GetPolyLine( 0 );
     const BaseGeometry *imageGeometry3D = m_InternalImage->GetGeometry( 0 );
 
     vtkPolyData *polyline = vtkPolyData::New();
     polyline->Allocate( 1, 1 );
 
     // Determine x- and y-dimensions depending on principal axis
     int i0, i1;
     switch ( axis )
     {
     case 0:
         i0 = 1;
         i1 = 2;
         break;
     case 1:
         i0 = 0;
         i1 = 2;
         break;
     case 2:
     default:
         i0 = 0;
         i1 = 1;
         break;
     }
 
     // Create VTK polydata object of polyline contour
     vtkPoints *points = vtkPoints::New();
     PlanarFigure::PolyLineType::const_iterator it;
     unsigned int numberOfPoints = 0;
 
     for ( it = planarFigurePolyline.begin(); it != planarFigurePolyline.end(); ++it )
     {
         Point3D point3D;
 
         // Convert 2D point back to the local index coordinates of the selected image
         Point2D point2D = *it;
         planarFigurePlaneGeometry->WorldToIndex(point2D, point2D);
         point2D[0] -= 0.5/m_UpsamplingFactor;
         point2D[1] -= 0.5/m_UpsamplingFactor;
         planarFigurePlaneGeometry->IndexToWorld(point2D, point2D);
         planarFigurePlaneGeometry->Map( point2D, point3D );
 
         // Polygons (partially) outside of the image bounds can not be processed further due to a bug in vtkPolyDataToImageStencil
         if ( !imageGeometry3D->IsInside( point3D ) )
         {
             float bounds[2] = {0,0};
             bounds[0] =
                     this->m_InternalImage->GetLargestPossibleRegion().GetSize().GetElement(i0);
             bounds[1] =
                     this->m_InternalImage->GetLargestPossibleRegion().GetSize().GetElement(i1);
 
             imageGeometry3D->WorldToIndex( point3D, point3D );
 
             if (point3D[i0]<0)
                 point3D[i0] = 0.0;
             else if (point3D[i0]>bounds[0])
                 point3D[i0] = bounds[0]-0.001;
 
             if (point3D[i1]<0)
                 point3D[i1] = 0.0;
             else if (point3D[i1]>bounds[1])
                 point3D[i1] = bounds[1]-0.001;
 
             points->InsertNextPoint( point3D[i0], point3D[i1], -0.5 );
             numberOfPoints++;
         }
         else
         {
             imageGeometry3D->WorldToIndex( point3D, point3D );
             // Add point to polyline array
             points->InsertNextPoint( point3D[i0], point3D[i1], -0.5 );
             numberOfPoints++;
         }
     }
     polyline->SetPoints( points );
     points->Delete();
 
     vtkIdType *ptIds = new vtkIdType[numberOfPoints];
     for ( vtkIdType i = 0; i < numberOfPoints; ++i )
         ptIds[i] = i;
     polyline->InsertNextCell( VTK_POLY_LINE, numberOfPoints, ptIds );
 
     // Extrude the generated contour polygon
     vtkLinearExtrusionFilter *extrudeFilter = vtkLinearExtrusionFilter::New();
     extrudeFilter->SetInputData( polyline );
     extrudeFilter->SetScaleFactor( 1 );
     extrudeFilter->SetExtrusionTypeToNormalExtrusion();
     extrudeFilter->SetVector( 0.0, 0.0, 1.0 );
 
     // Make a stencil from the extruded polygon
     vtkPolyDataToImageStencil *polyDataToImageStencil = vtkPolyDataToImageStencil::New();
     polyDataToImageStencil->SetInputConnection( extrudeFilter->GetOutputPort() );
 
     // Export from ITK to VTK (to use a VTK filter)
     typedef itk::VTKImageImport< itkUCharImageType > ImageImportType;
     typedef itk::VTKImageExport< itkUCharImageType > ImageExportType;
 
     typename ImageExportType::Pointer itkExporter = ImageExportType::New();
     itkExporter->SetInput( newMaskImage );
 
     vtkImageImport *vtkImporter = vtkImageImport::New();
     this->ConnectPipelines( itkExporter, vtkImporter );
     vtkImporter->Update();
 
     // Apply the generated image stencil to the input image
     vtkImageStencil *imageStencilFilter = vtkImageStencil::New();
     imageStencilFilter->SetInputConnection( vtkImporter->GetOutputPort() );
     imageStencilFilter->SetStencilConnection(polyDataToImageStencil->GetOutputPort() );
     imageStencilFilter->ReverseStencilOff();
     imageStencilFilter->SetBackgroundValue( 0 );
     imageStencilFilter->Update();
 
     // Export from VTK back to ITK
     vtkImageExport *vtkExporter = vtkImageExport::New();
     vtkExporter->SetInputConnection( imageStencilFilter->GetOutputPort() );
     vtkExporter->Update();
 
     typename ImageImportType::Pointer itkImporter = ImageImportType::New();
     this->ConnectPipelines( vtkExporter, itkImporter );
     itkImporter->Update();
 
     // calculate cropping bounding box
     m_InternalImageMask3D = itkImporter->GetOutput();
     m_InternalImageMask3D->SetDirection(image->GetDirection());
 
     itk::ImageRegionConstIterator<itkUCharImageType>
             itmask(m_InternalImageMask3D, m_InternalImageMask3D->GetLargestPossibleRegion());
     itk::ImageRegionIterator<ImageType>
             itimage(image, image->GetLargestPossibleRegion());
 
     itmask.GoToBegin();
     itimage.GoToBegin();
 
     typename ImageType::SizeType lowersize = {{itk::NumericTraits<unsigned long>::max(),itk::NumericTraits<unsigned long>::max(),itk::NumericTraits<unsigned long>::max()}};
     typename ImageType::SizeType uppersize = {{0,0,0}};
     while( !itmask.IsAtEnd() )
     {
         if(itmask.Get() == 0)
             itimage.Set(0);
         else
         {
             typename ImageType::IndexType index = itimage.GetIndex();
             typename ImageType::SizeType signedindex;
             signedindex[0] = index[0];
             signedindex[1] = index[1];
             signedindex[2] = index[2];
 
             lowersize[0] = signedindex[0] < lowersize[0] ? signedindex[0] : lowersize[0];
             lowersize[1] = signedindex[1] < lowersize[1] ? signedindex[1] : lowersize[1];
             lowersize[2] = signedindex[2] < lowersize[2] ? signedindex[2] : lowersize[2];
 
             uppersize[0] = signedindex[0] > uppersize[0] ? signedindex[0] : uppersize[0];
             uppersize[1] = signedindex[1] > uppersize[1] ? signedindex[1] : uppersize[1];
             uppersize[2] = signedindex[2] > uppersize[2] ? signedindex[2] : uppersize[2];
         }
 
         ++itmask;
         ++itimage;
     }
 
     typename ImageType::IndexType index;
     index[0] = lowersize[0];
     index[1] = lowersize[1];
     index[2] = lowersize[2];
 
     typename ImageType::SizeType size;
     size[0] = uppersize[0] - lowersize[0] + 1;
     size[1] = uppersize[1] - lowersize[1] + 1;
     size[2] = uppersize[2] - lowersize[2] + 1;
 
     itk::ImageRegion<3> cropRegion = itk::ImageRegion<3>(index, size);
 
     // crop internal mask
     typedef itk::RegionOfInterestImageFilter< itkUCharImageType, itkUCharImageType > ROIMaskFilterType;
     typename ROIMaskFilterType::Pointer roi2 = ROIMaskFilterType::New();
     roi2->SetRegionOfInterest(cropRegion);
     roi2->SetInput(m_InternalImageMask3D);
     roi2->Update();
     m_InternalImageMask3D = roi2->GetOutput();
 
     Image::Pointer tmpImage = Image::New();
     tmpImage->InitializeByItk(m_InternalImageMask3D.GetPointer());
     tmpImage->SetVolume(m_InternalImageMask3D->GetBufferPointer());
 
     Image::Pointer tmpImage2 = Image::New();
     tmpImage2->InitializeByItk(m_PlanarFigureImage.GetPointer());
     const BaseGeometry *pfImageGeometry3D = tmpImage2->GetGeometry( 0 );
 
     const BaseGeometry *intImageGeometry3D = tmpImage->GetGeometry( 0 );
 
     typedef itk::ImageRegionIteratorWithIndex<itkUCharImageType> IteratorType;
     IteratorType imageIterator (m_InternalImageMask3D, m_InternalImageMask3D->GetRequestedRegion());
     imageIterator.GoToBegin();
     while ( !imageIterator.IsAtEnd() )
     {
         unsigned char val = imageIterator.Value();
         if (val>0)
         {
             itk::Index<3> index = imageIterator.GetIndex();
             Point3D point;
             point[0] = index[0];
             point[1] = index[1];
             point[2] = index[2];
 
             intImageGeometry3D->IndexToWorld(point, point);
             pfImageGeometry3D->WorldToIndex(point, point);
 
             point[i0] += 0.5;
             point[i1] += 0.5;
 
             index[0] = point[0];
             index[1] = point[1];
             index[2] = point[2];
 
             if (pfImageGeometry3D->IsIndexInside(index))
                 m_PlanarFigureImage->SetPixel(index, 1);
         }
         ++imageIterator;
     }
 
     // Clean up VTK objects
     polyline->Delete();
     extrudeFilter->Delete();
     polyDataToImageStencil->Delete();
     vtkImporter->Delete();
     imageStencilFilter->Delete();
     //vtkExporter->Delete(); // TODO: crashes when outcommented; memory leak??
     delete[] ptIds;
 }
 
 void QmitkFiberProcessingView::StdMultiWidgetAvailable (QmitkStdMultiWidget &stdMultiWidget)
 {
     m_MultiWidget = &stdMultiWidget;
 }
 
 void QmitkFiberProcessingView::StdMultiWidgetNotAvailable()
 {
     m_MultiWidget = NULL;
 }
 
 void QmitkFiberProcessingView::UpdateGui()
 {
     m_Controls->m_FibLabel->setText("<font color='red'>mandatory</font>");
     m_Controls->m_PfLabel->setText("<font color='grey'>needed for extraction</font>");
     m_Controls->m_InputData->setTitle("Please Select Input Data");
 
     m_Controls->m_RemoveButton->setEnabled(false);
 
     m_Controls->m_PlanarFigureButtonsFrame->setEnabled(false);
     m_Controls->PFCompoANDButton->setEnabled(false);
     m_Controls->PFCompoORButton->setEnabled(false);
     m_Controls->PFCompoNOTButton->setEnabled(false);
 
     m_Controls->m_GenerateRoiImage->setEnabled(false);
     m_Controls->m_ExtractFibersButton->setEnabled(false);
     m_Controls->m_ModifyButton->setEnabled(false);
 
     m_Controls->m_JoinBundles->setEnabled(false);
     m_Controls->m_SubstractBundles->setEnabled(false);
 
     // disable alle frames
     m_Controls->m_BundleWeightFrame->setVisible(false);
     m_Controls->m_ExtractionBoxMask->setVisible(false);
     m_Controls->m_ExtactionFramePF->setVisible(false);
     m_Controls->m_RemoveDirectionFrame->setVisible(false);
     m_Controls->m_RemoveLengthFrame->setVisible(false);
     m_Controls->m_RemoveCurvatureFrame->setVisible(false);
     m_Controls->m_SmoothFibersFrame->setVisible(false);
     m_Controls->m_CompressFibersFrame->setVisible(false);
     m_Controls->m_ColorFibersFrame->setVisible(false);
     m_Controls->m_MirrorFibersFrame->setVisible(false);
 
     bool pfSelected = !m_SelectedPF.empty();
     bool fibSelected = !m_SelectedFB.empty();
     bool multipleFibsSelected = (m_SelectedFB.size()>1);
     bool maskSelected = m_MaskImageNode.IsNotNull();
     bool imageSelected = m_SelectedImage.IsNotNull();
 
     // toggle visibility of elements according to selected method
     switch ( m_Controls->m_ExtractionMethodBox->currentIndex() )
     {
     case 0:
         m_Controls->m_ExtactionFramePF->setVisible(true);
         break;
     case 1:
         m_Controls->m_ExtractionBoxMask->setVisible(true);
         break;
     }
 
     switch ( m_Controls->m_RemovalMethodBox->currentIndex() )
     {
     case 0:
         m_Controls->m_RemoveDirectionFrame->setVisible(true);
         if ( fibSelected )
             m_Controls->m_RemoveButton->setEnabled(true);
         break;
     case 1:
         m_Controls->m_RemoveLengthFrame->setVisible(true);
         if ( fibSelected )
             m_Controls->m_RemoveButton->setEnabled(true);
         break;
     case 2:
         m_Controls->m_RemoveCurvatureFrame->setVisible(true);
         if ( fibSelected )
             m_Controls->m_RemoveButton->setEnabled(true);
         break;
     case 3:
         break;
     case 4:
         break;
     }
 
     switch ( m_Controls->m_ModificationMethodBox->currentIndex() )
     {
     case 0:
         m_Controls->m_SmoothFibersFrame->setVisible(true);
         break;
     case 1:
         m_Controls->m_CompressFibersFrame->setVisible(true);
         break;
     case 2:
         m_Controls->m_ColorFibersFrame->setVisible(true);
         break;
     case 3:
         m_Controls->m_MirrorFibersFrame->setVisible(true);
         break;
     case 4:
         m_Controls->m_BundleWeightFrame->setVisible(true);
     }
 
     // are fiber bundles selected?
     if ( fibSelected )
     {
         m_Controls->m_ModifyButton->setEnabled(true);
         m_Controls->m_PlanarFigureButtonsFrame->setEnabled(true);
         m_Controls->m_FibLabel->setText(QString(m_SelectedFB.at(0)->GetName().c_str()));
 
         // one bundle and one planar figure needed to extract fibers
         if (pfSelected)
         {
             m_Controls->m_InputData->setTitle("Input Data");
             m_Controls->m_PfLabel->setText(QString(m_SelectedPF.at(0)->GetName().c_str()));
             m_Controls->m_ExtractFibersButton->setEnabled(true);
         }
 
         // more than two bundles needed to join/subtract
         if (multipleFibsSelected)
         {
             m_Controls->m_FibLabel->setText("multiple bundles selected");
 
             m_Controls->m_JoinBundles->setEnabled(true);
             m_Controls->m_SubstractBundles->setEnabled(true);
         }
 
         if (maskSelected)
         {
             m_Controls->m_RemoveButton->setEnabled(true);
             m_Controls->m_ExtractFibersButton->setEnabled(true);
         }
     }
 
     // are planar figures selected?
     if (pfSelected)
     {
         if ( fibSelected || m_SelectedImage.IsNotNull())
             m_Controls->m_GenerateRoiImage->setEnabled(true);
 
         if (m_SelectedPF.size() > 1)
         {
             m_Controls->PFCompoANDButton->setEnabled(true);
             m_Controls->PFCompoORButton->setEnabled(true);
         }
         else
             m_Controls->PFCompoNOTButton->setEnabled(true);
     }
 
     // is image selected
     if (imageSelected || maskSelected)
     {
         m_Controls->m_PlanarFigureButtonsFrame->setEnabled(true);
     }
 }
 
 void QmitkFiberProcessingView::NodeRemoved(const mitk::DataNode* node)
 {
     std::vector<mitk::DataNode*> nodes;
     OnSelectionChanged(nodes);
 }
 
 void QmitkFiberProcessingView::NodeAdded(const mitk::DataNode* node)
 {
     std::vector<mitk::DataNode*> nodes;
     OnSelectionChanged(nodes);
 }
 
 void QmitkFiberProcessingView::OnSelectionChanged( std::vector<mitk::DataNode*> nodes )
 {
     //reset existing Vectors containing FiberBundles and PlanarFigures from a previous selection
     m_SelectedFB.clear();
     m_SelectedPF.clear();
     m_SelectedSurfaces.clear();
     m_SelectedImage = NULL;
     m_MaskImageNode = NULL;
 
     for( std::vector<mitk::DataNode*>::iterator it = nodes.begin(); it != nodes.end(); ++it )
     {
         mitk::DataNode::Pointer node = *it;
         if ( dynamic_cast<mitk::FiberBundle*>(node->GetData()) )
             m_SelectedFB.push_back(node);
         else if (dynamic_cast<mitk::PlanarPolygon*>(node->GetData()) || dynamic_cast<mitk::PlanarFigureComposite*>(node->GetData()) || dynamic_cast<mitk::PlanarCircle*>(node->GetData()))
             m_SelectedPF.push_back(node);
         else if (dynamic_cast<mitk::Image*>(node->GetData()))
         {
             m_SelectedImage = dynamic_cast<mitk::Image*>(node->GetData());
             bool isBinary = false;
             node->GetPropertyValue<bool>("binary", isBinary);
             if (isBinary)
                 m_MaskImageNode = node;
         }
         else if (dynamic_cast<mitk::Surface*>(node->GetData()))
             m_SelectedSurfaces.push_back(dynamic_cast<mitk::Surface*>(node->GetData()));
     }
 
     if (m_SelectedFB.empty())
     {
         int maxLayer = 0;
         itk::VectorContainer<unsigned int, mitk::DataNode::Pointer>::ConstPointer nodes = this->GetDefaultDataStorage()->GetAll();
         for (unsigned int i=0; i<nodes->Size(); i++)
             if (dynamic_cast<mitk::FiberBundle*>(nodes->at(i)->GetData()))
             {
                 mitk::DataStorage::SetOfObjects::ConstPointer sources = GetDataStorage()->GetSources(nodes->at(i));
                 if (sources->Size()>0)
                     continue;
 
                 int layer = 0;
                 nodes->at(i)->GetPropertyValue("layer", layer);
                 if (layer>=maxLayer)
                 {
                     maxLayer = layer;
                     m_SelectedFB.clear();
                     m_SelectedFB.push_back(nodes->at(i));
                 }
             }
     }
 
     if (m_SelectedPF.empty())
     {
         int maxLayer = 0;
         itk::VectorContainer<unsigned int, mitk::DataNode::Pointer>::ConstPointer nodes = this->GetDefaultDataStorage()->GetAll();
         for (unsigned int i=0; i<nodes->Size(); i++)
             if (dynamic_cast<mitk::PlanarPolygon*>(nodes->at(i)->GetData()) || dynamic_cast<mitk::PlanarFigureComposite*>(nodes->at(i)->GetData()) || dynamic_cast<mitk::PlanarCircle*>(nodes->at(i)->GetData()))
             {
                 mitk::DataStorage::SetOfObjects::ConstPointer sources = GetDataStorage()->GetSources(nodes->at(i));
                 if (sources->Size()>0)
                     continue;
 
                 int layer = 0;
                 nodes->at(i)->GetPropertyValue("layer", layer);
                 if (layer>=maxLayer)
                 {
                     maxLayer = layer;
                     m_SelectedPF.clear();
                     m_SelectedPF.push_back(nodes->at(i));
                 }
             }
     }
 
     UpdateGui();
 }
 
 void QmitkFiberProcessingView::OnDrawPolygon()
 {
     mitk::PlanarPolygon::Pointer figure = mitk::PlanarPolygon::New();
     figure->ClosedOn();
     this->AddFigureToDataStorage(figure, QString("Polygon%1").arg(++m_PolygonCounter));
 }
 
 void QmitkFiberProcessingView::OnDrawCircle()
 {
     mitk::PlanarCircle::Pointer figure = mitk::PlanarCircle::New();
     this->AddFigureToDataStorage(figure, QString("Circle%1").arg(++m_CircleCounter));
 }
 
 void QmitkFiberProcessingView::Activated()
 {
 
 }
 
 void QmitkFiberProcessingView::AddFigureToDataStorage(mitk::PlanarFigure* figure, const QString& name, const char *, mitk::BaseProperty* )
 {
     // initialize figure's geometry with empty geometry
     mitk::PlaneGeometry::Pointer emptygeometry = mitk::PlaneGeometry::New();
     figure->SetPlaneGeometry( emptygeometry );
 
     //set desired data to DataNode where Planarfigure is stored
     mitk::DataNode::Pointer newNode = mitk::DataNode::New();
     newNode->SetName(name.toStdString());
     newNode->SetData(figure);
     newNode->SetBoolProperty("planarfigure.3drendering", true);
     newNode->SetBoolProperty("planarfigure.3drendering.fill", true);
 
     mitk::PlanarFigureInteractor::Pointer figureInteractor = dynamic_cast<mitk::PlanarFigureInteractor*>(newNode->GetDataInteractor().GetPointer());
     if(figureInteractor.IsNull())
     {
         figureInteractor = mitk::PlanarFigureInteractor::New();
         us::Module* planarFigureModule = us::ModuleRegistry::GetModule( "MitkPlanarFigure" );
         figureInteractor->LoadStateMachine("PlanarFigureInteraction.xml", planarFigureModule );
         figureInteractor->SetEventConfig( "PlanarFigureConfig.xml", planarFigureModule );
         figureInteractor->SetDataNode(newNode);
     }
 
     // figure drawn on the topmost layer / image
     GetDataStorage()->Add(newNode );
 
     for(unsigned int i = 0; i < m_SelectedPF.size(); i++)
         m_SelectedPF[i]->SetSelected(false);
 
     newNode->SetSelected(true);
     m_SelectedPF.clear();
     m_SelectedPF.push_back(newNode);
     UpdateGui();
 }
 
 void QmitkFiberProcessingView::ExtractWithPlanarFigure()
 {
     if ( m_SelectedFB.empty() || m_SelectedPF.empty() ){
         QMessageBox::information( NULL, "Warning", "No fibe bundle selected!");
         return;
     }
 
     std::vector<mitk::DataNode::Pointer> fiberBundles = m_SelectedFB;
     mitk::DataNode::Pointer planarFigure = m_SelectedPF.at(0);
     for (unsigned int i=0; i<fiberBundles.size(); i++)
     {
         mitk::FiberBundle::Pointer fib = dynamic_cast<mitk::FiberBundle*>(fiberBundles.at(i)->GetData());
 
         mitk::FiberBundle::Pointer extFB = fib->ExtractFiberSubset(planarFigure, GetDataStorage());
         if (extFB->GetNumFibers()<=0)
         {
             QMessageBox::information(NULL, "No output generated:", "The resulting fiber bundle contains no fibers.");
             continue;
         }
 
         mitk::DataNode::Pointer node;
         node = mitk::DataNode::New();
         node->SetData(extFB);
         QString name(fiberBundles.at(i)->GetName().c_str());
-        name += "_";
-        name += planarFigure->GetName().c_str();
+        name += "*";
+        //name += planarFigure->GetName().c_str();
         node->SetName(name.toStdString());
         fiberBundles.at(i)->SetVisibility(false);
         GetDataStorage()->Add(node);
     }
 }
 
 void QmitkFiberProcessingView::GenerateAndComposite()
 {
     mitk::PlanarFigureComposite::Pointer PFCAnd = mitk::PlanarFigureComposite::New();
     PFCAnd->setOperationType(mitk::PlanarFigureComposite::AND);
 
     mitk::DataNode::Pointer newPFCNode;
     newPFCNode = mitk::DataNode::New();
     newPFCNode->SetName("AND");
     newPFCNode->SetData(PFCAnd);
 
     AddCompositeToDatastorage(newPFCNode, m_SelectedPF);
     m_SelectedPF.clear();
     m_SelectedPF.push_back(newPFCNode);
     UpdateGui();
 }
 
 void QmitkFiberProcessingView::GenerateOrComposite()
 {
     mitk::PlanarFigureComposite::Pointer PFCOr = mitk::PlanarFigureComposite::New();
     PFCOr->setOperationType(mitk::PlanarFigureComposite::OR);
 
     mitk::DataNode::Pointer newPFCNode;
     newPFCNode = mitk::DataNode::New();
     newPFCNode->SetName("OR");
     newPFCNode->SetData(PFCOr);
 
     AddCompositeToDatastorage(newPFCNode, m_SelectedPF);
     m_SelectedPF.clear();
     m_SelectedPF.push_back(newPFCNode);
     UpdateGui();
 }
 
 void QmitkFiberProcessingView::GenerateNotComposite()
 {
     mitk::PlanarFigureComposite::Pointer PFCNot = mitk::PlanarFigureComposite::New();
     PFCNot->setOperationType(mitk::PlanarFigureComposite::NOT);
 
     mitk::DataNode::Pointer newPFCNode;
     newPFCNode = mitk::DataNode::New();
     newPFCNode->SetName("NOT");
     newPFCNode->SetData(PFCNot);
 
     AddCompositeToDatastorage(newPFCNode, m_SelectedPF);
     m_SelectedPF.clear();
     m_SelectedPF.push_back(newPFCNode);
     UpdateGui();
 }
 
 void QmitkFiberProcessingView::AddCompositeToDatastorage(mitk::DataNode::Pointer pfc, std::vector<mitk::DataNode::Pointer> children, mitk::DataNode::Pointer parentNode )
 {
     pfc->SetSelected(true);
     if (parentNode.IsNotNull())
         GetDataStorage()->Add(pfc, parentNode);
     else
         GetDataStorage()->Add(pfc);
 
     for (int i=0; i<children.size(); i++)
     {
         if (dynamic_cast<PlanarFigure*>(children.at(i)->GetData()))
         {
             mitk::DataNode::Pointer newChild;
             newChild = mitk::DataNode::New();
             newChild->SetData(dynamic_cast<PlanarFigure*>(children.at(i)->GetData()));
             newChild->SetName( children.at(i)->GetName() );
 
             GetDataStorage()->Add(newChild, pfc);
             GetDataStorage()->Remove(children.at(i));
         }
         else if (dynamic_cast<PlanarFigureComposite*>(children.at(i)->GetData()))
         {
             mitk::DataNode::Pointer newChild;
             newChild = mitk::DataNode::New();
             newChild->SetData(dynamic_cast<PlanarFigureComposite*>(children.at(i)->GetData()));
             newChild->SetName( children.at(i)->GetName() );
 
             std::vector< mitk::DataNode::Pointer > grandChildVector;
             mitk::DataStorage::SetOfObjects::ConstPointer grandchildren = GetDataStorage()->GetDerivations(children.at(i));
             for( mitk::DataStorage::SetOfObjects::const_iterator it = grandchildren->begin(); it != grandchildren->end(); ++it )
                 grandChildVector.push_back(*it);
 
             AddCompositeToDatastorage(newChild, grandChildVector, pfc);
             GetDataStorage()->Remove(children.at(i));
         }
     }
 }
 
 void QmitkFiberProcessingView::JoinBundles()
 {
     if ( m_SelectedFB.size()<2 ){
         QMessageBox::information( NULL, "Warning", "Select at least two fiber bundles!");
         MITK_WARN("QmitkFiberProcessingView") << "Select at least two fiber bundles!";
         return;
     }
 
     mitk::FiberBundle::Pointer newBundle = dynamic_cast<mitk::FiberBundle*>(m_SelectedFB.at(0)->GetData());
     m_SelectedFB.at(0)->SetVisibility(false);
     QString name("");
     name += QString(m_SelectedFB.at(0)->GetName().c_str());
     for (unsigned int i=1; i<m_SelectedFB.size(); i++)
     {
         newBundle = newBundle->AddBundle(dynamic_cast<mitk::FiberBundle*>(m_SelectedFB.at(i)->GetData()));
         name += "+"+QString(m_SelectedFB.at(i)->GetName().c_str());
         m_SelectedFB.at(i)->SetVisibility(false);
     }
 
     mitk::DataNode::Pointer fbNode = mitk::DataNode::New();
     fbNode->SetData(newBundle);
     fbNode->SetName(name.toStdString());
     fbNode->SetVisibility(true);
     GetDataStorage()->Add(fbNode);
 }
 
 void QmitkFiberProcessingView::SubstractBundles()
 {
     if ( m_SelectedFB.size()<2 ){
         QMessageBox::information( NULL, "Warning", "Select at least two fiber bundles!");
         MITK_WARN("QmitkFiberProcessingView") << "Select at least two fiber bundles!";
         return;
     }
 
     mitk::FiberBundle::Pointer newBundle = dynamic_cast<mitk::FiberBundle*>(m_SelectedFB.at(0)->GetData());
     m_SelectedFB.at(0)->SetVisibility(false);
     QString name("");
     name += QString(m_SelectedFB.at(0)->GetName().c_str());
     for (unsigned int i=1; i<m_SelectedFB.size(); i++)
     {
         newBundle = newBundle->SubtractBundle(dynamic_cast<mitk::FiberBundle*>(m_SelectedFB.at(i)->GetData()));
         if (newBundle.IsNull())
             break;
         name += "-"+QString(m_SelectedFB.at(i)->GetName().c_str());
         m_SelectedFB.at(i)->SetVisibility(false);
     }
     if (newBundle.IsNull())
     {
         QMessageBox::information(NULL, "No output generated:", "The resulting fiber bundle contains no fibers. Did you select the fiber bundles in the correct order? X-Y is not equal to Y-X!");
         return;
     }
 
     mitk::DataNode::Pointer fbNode = mitk::DataNode::New();
     fbNode->SetData(newBundle);
     fbNode->SetName(name.toStdString());
     fbNode->SetVisibility(true);
     GetDataStorage()->Add(fbNode);
 }
 
 void QmitkFiberProcessingView::ResampleSelectedBundles()
 {
     double factor = this->m_Controls->m_SmoothFibersBox->value();
     for (unsigned int i=0; i<m_SelectedFB.size(); i++)
     {
         mitk::FiberBundle::Pointer fib = dynamic_cast<mitk::FiberBundle*>(m_SelectedFB.at(i)->GetData());
         fib->ResampleSpline(factor);
     }
     RenderingManager::GetInstance()->RequestUpdateAll();
 }
 
 void QmitkFiberProcessingView::CompressSelectedBundles()
 {
     double factor = this->m_Controls->m_ErrorThresholdBox->value();
     for (unsigned int i=0; i<m_SelectedFB.size(); i++)
     {
         mitk::FiberBundle::Pointer fib = dynamic_cast<mitk::FiberBundle*>(m_SelectedFB.at(i)->GetData());
         fib->Compress(factor);
     }
     RenderingManager::GetInstance()->RequestUpdateAll();
 }
 
 void QmitkFiberProcessingView::DoImageColorCoding()
 {
     if (m_Controls->m_ColorMapBox->GetSelectedNode().IsNull())
     {
         QMessageBox::information(NULL, "Bundle coloring aborted:", "No image providing the scalar values for coloring the selected bundle available.");
         return;
     }
 
     for(unsigned int i=0; i<m_SelectedFB.size(); i++ )
     {
         mitk::FiberBundle::Pointer fib = dynamic_cast<mitk::FiberBundle*>(m_SelectedFB.at(i)->GetData());
         fib->ColorFibersByScalarMap(dynamic_cast<mitk::Image*>(m_Controls->m_ColorMapBox->GetSelectedNode()->GetData()), m_Controls->m_FiberOpacityBox->isChecked());
     }
 
     if(m_MultiWidget)
         m_MultiWidget->RequestUpdate();
 }
 
 
 void QmitkFiberProcessingView::DoCurvatureColorCoding()
 {
     for(unsigned int i=0; i<m_SelectedFB.size(); i++ )
     {
         mitk::FiberBundle::Pointer fib = dynamic_cast<mitk::FiberBundle*>(m_SelectedFB.at(i)->GetData());
         fib->ColorFibersByCurvature();
     }
 
     if(m_MultiWidget)
         m_MultiWidget->RequestUpdate();
 }
 
 void QmitkFiberProcessingView::MirrorFibers()
 {
     unsigned int axis = this->m_Controls->m_MirrorFibersBox->currentIndex();
     for (int i=0; i<m_SelectedFB.size(); i++)
     {
         mitk::FiberBundle::Pointer fib = dynamic_cast<mitk::FiberBundle*>(m_SelectedFB.at(i)->GetData());
+        if (m_SelectedImage.IsNotNull())
+            fib->SetReferenceGeometry(m_SelectedImage->GetGeometry());
         fib->MirrorFibers(axis);
     }
 
     if (m_SelectedSurfaces.size()>0)
     {
         for (int i=0; i<m_SelectedSurfaces.size(); i++)
         {
             mitk::Surface::Pointer surf = m_SelectedSurfaces.at(i);
             vtkSmartPointer<vtkPolyData> poly = surf->GetVtkPolyData();
             vtkSmartPointer<vtkPoints> vtkNewPoints = vtkSmartPointer<vtkPoints>::New();
 
             for (int i=0; i<poly->GetNumberOfPoints(); i++)
             {
                 double* point = poly->GetPoint(i);
                 point[axis] *= -1;
                 vtkNewPoints->InsertNextPoint(point);
             }
             poly->SetPoints(vtkNewPoints);
             surf->CalculateBoundingBox();
         }
     }
 
     RenderingManager::GetInstance()->RequestUpdateAll();
 }
diff --git a/Plugins/org.mitk.gui.qt.diffusionimaging/src/internal/QmitkFiberProcessingViewControls.ui b/Plugins/org.mitk.gui.qt.diffusionimaging/src/internal/QmitkFiberProcessingViewControls.ui
index df61dedca9..f26e24c7fa 100644
--- a/Plugins/org.mitk.gui.qt.diffusionimaging/src/internal/QmitkFiberProcessingViewControls.ui
+++ b/Plugins/org.mitk.gui.qt.diffusionimaging/src/internal/QmitkFiberProcessingViewControls.ui
@@ -1,1325 +1,1325 @@
 <?xml version="1.0" encoding="UTF-8"?>
 <ui version="4.0">
  <class>QmitkFiberProcessingViewControls</class>
  <widget class="QWidget" name="QmitkFiberProcessingViewControls">
   <property name="geometry">
    <rect>
     <x>0</x>
     <y>0</y>
     <width>386</width>
     <height>540</height>
    </rect>
   </property>
   <property name="windowTitle">
    <string>Form</string>
   </property>
   <layout class="QGridLayout" name="gridLayout_3">
    <item row="1" column="0">
     <widget class="QToolBox" name="toolBoxx">
      <property name="currentIndex">
       <number>0</number>
      </property>
      <widget class="QWidget" name="page">
       <property name="geometry">
        <rect>
         <x>0</x>
         <y>0</y>
         <width>355</width>
         <height>308</height>
        </rect>
       </property>
       <attribute name="label">
        <string>Fiber Extraction</string>
       </attribute>
       <attribute name="toolTip">
        <string>Extract a fiber subset from the selected fiber bundle using manually placed planar figures as waypoints or binary regions of interest.</string>
       </attribute>
       <layout class="QGridLayout" name="gridLayout_14">
        <item row="5" column="0">
         <widget class="QCommandLinkButton" name="m_ExtractFibersButton">
          <property name="enabled">
           <bool>false</bool>
          </property>
          <property name="sizePolicy">
           <sizepolicy hsizetype="Preferred" vsizetype="Preferred">
            <horstretch>0</horstretch>
            <verstretch>0</verstretch>
           </sizepolicy>
          </property>
          <property name="maximumSize">
           <size>
            <width>200</width>
            <height>16777215</height>
           </size>
          </property>
          <property name="font">
           <font>
            <pointsize>11</pointsize>
           </font>
          </property>
          <property name="toolTip">
           <string>Extract fibers passing through selected ROI or composite ROI. Select ROI and fiber bundle to execute.</string>
          </property>
          <property name="text">
           <string>Extract</string>
          </property>
         </widget>
        </item>
        <item row="6" column="0">
         <spacer name="verticalSpacer_5">
          <property name="orientation">
           <enum>Qt::Vertical</enum>
          </property>
          <property name="sizeHint" stdset="0">
           <size>
            <width>20</width>
            <height>40</height>
           </size>
          </property>
         </spacer>
        </item>
        <item row="4" column="0">
         <widget class="QComboBox" name="m_ExtractionBoxMask">
          <property name="sizePolicy">
           <sizepolicy hsizetype="Expanding" vsizetype="Fixed">
            <horstretch>0</horstretch>
            <verstretch>0</verstretch>
           </sizepolicy>
          </property>
          <item>
           <property name="text">
            <string>Ending in mask</string>
           </property>
          </item>
          <item>
           <property name="text">
            <string>Not ending in mask</string>
           </property>
          </item>
          <item>
           <property name="text">
            <string>Passing mask</string>
           </property>
          </item>
          <item>
           <property name="text">
            <string>Not passing mask</string>
           </property>
          </item>
         </widget>
        </item>
        <item row="3" column="0">
         <widget class="QFrame" name="m_ExtactionFramePF">
          <property name="frameShape">
           <enum>QFrame::NoFrame</enum>
          </property>
          <property name="frameShadow">
           <enum>QFrame::Raised</enum>
          </property>
          <layout class="QGridLayout" name="gridLayout_8">
           <property name="leftMargin">
            <number>9</number>
           </property>
           <property name="topMargin">
            <number>9</number>
           </property>
           <property name="rightMargin">
            <number>9</number>
           </property>
           <property name="bottomMargin">
            <number>9</number>
           </property>
           <property name="spacing">
            <number>0</number>
           </property>
           <item row="2" column="0">
            <widget class="QCommandLinkButton" name="m_GenerateRoiImage">
             <property name="enabled">
              <bool>false</bool>
             </property>
             <property name="sizePolicy">
              <sizepolicy hsizetype="Preferred" vsizetype="Preferred">
               <horstretch>0</horstretch>
               <verstretch>0</verstretch>
              </sizepolicy>
             </property>
             <property name="maximumSize">
              <size>
               <width>16777215</width>
               <height>16777215</height>
              </size>
             </property>
             <property name="font">
              <font>
               <pointsize>11</pointsize>
              </font>
             </property>
             <property name="toolTip">
              <string>Generate a binary image containing all selected ROIs. Select at least one ROI (planar figure) and a reference fiber bundle or image.</string>
             </property>
             <property name="text">
              <string>Generate ROI Image</string>
             </property>
            </widget>
           </item>
           <item row="1" column="0">
            <widget class="QFrame" name="m_PlanarFigureButtonsFrame_2">
             <property name="sizePolicy">
              <sizepolicy hsizetype="Preferred" vsizetype="Preferred">
               <horstretch>0</horstretch>
               <verstretch>0</verstretch>
              </sizepolicy>
             </property>
             <property name="minimumSize">
              <size>
               <width>200</width>
               <height>0</height>
              </size>
             </property>
             <property name="maximumSize">
              <size>
               <width>16777215</width>
               <height>60</height>
              </size>
             </property>
             <property name="frameShape">
              <enum>QFrame::NoFrame</enum>
             </property>
             <property name="frameShadow">
              <enum>QFrame::Raised</enum>
             </property>
             <layout class="QGridLayout" name="gridLayout_5">
              <property name="leftMargin">
               <number>0</number>
              </property>
              <property name="topMargin">
               <number>0</number>
              </property>
              <property name="rightMargin">
               <number>0</number>
              </property>
              <property name="bottomMargin">
               <number>0</number>
              </property>
              <item row="0" column="1">
               <widget class="QCommandLinkButton" name="PFCompoORButton">
                <property name="enabled">
                 <bool>false</bool>
                </property>
                <property name="maximumSize">
                 <size>
                  <width>60</width>
                  <height>16777215</height>
                 </size>
                </property>
                <property name="toolTip">
                 <string>Create OR composition with selected ROIs.</string>
                </property>
                <property name="text">
                 <string>OR</string>
                </property>
               </widget>
              </item>
              <item row="0" column="3">
               <spacer name="horizontalSpacer_3">
                <property name="orientation">
                 <enum>Qt::Horizontal</enum>
                </property>
                <property name="sizeHint" stdset="0">
                 <size>
                  <width>40</width>
                  <height>20</height>
                 </size>
                </property>
               </spacer>
              </item>
              <item row="0" column="2">
               <widget class="QCommandLinkButton" name="PFCompoNOTButton">
                <property name="enabled">
                 <bool>false</bool>
                </property>
                <property name="maximumSize">
                 <size>
                  <width>60</width>
                  <height>16777215</height>
                 </size>
                </property>
                <property name="toolTip">
                 <string>Create NOT composition from selected ROI.</string>
                </property>
                <property name="text">
                 <string>NOT</string>
                </property>
               </widget>
              </item>
              <item row="0" column="0">
               <widget class="QCommandLinkButton" name="PFCompoANDButton">
                <property name="enabled">
                 <bool>false</bool>
                </property>
                <property name="maximumSize">
                 <size>
                  <width>60</width>
                  <height>16777215</height>
                 </size>
                </property>
                <property name="toolTip">
                 <string>Create AND composition with selected ROIs.</string>
                </property>
                <property name="text">
                 <string>AND</string>
                </property>
               </widget>
              </item>
             </layout>
            </widget>
           </item>
           <item row="0" column="0">
            <widget class="QFrame" name="m_PlanarFigureButtonsFrame">
             <property name="sizePolicy">
              <sizepolicy hsizetype="Preferred" vsizetype="Preferred">
               <horstretch>0</horstretch>
               <verstretch>0</verstretch>
              </sizepolicy>
             </property>
             <property name="minimumSize">
              <size>
               <width>200</width>
               <height>0</height>
              </size>
             </property>
             <property name="maximumSize">
              <size>
               <width>16777215</width>
               <height>60</height>
              </size>
             </property>
             <property name="frameShape">
              <enum>QFrame::NoFrame</enum>
             </property>
             <property name="frameShadow">
              <enum>QFrame::Raised</enum>
             </property>
             <layout class="QGridLayout" name="gridLayout">
              <property name="leftMargin">
               <number>0</number>
              </property>
              <property name="topMargin">
               <number>0</number>
              </property>
              <property name="rightMargin">
               <number>0</number>
              </property>
              <property name="bottomMargin">
               <number>0</number>
              </property>
              <item row="0" column="0">
               <widget class="QPushButton" name="m_CircleButton">
                <property name="maximumSize">
                 <size>
                  <width>30</width>
                  <height>30</height>
                 </size>
                </property>
                <property name="toolTip">
                 <string>Draw circular ROI. Select reference fiber bundle to execute.</string>
                </property>
                <property name="text">
                 <string/>
                </property>
                <property name="icon">
                 <iconset resource="../../resources/QmitkDiffusionImaging.qrc">
                  <normaloff>:/QmitkDiffusionImaging/circle.png</normaloff>:/QmitkDiffusionImaging/circle.png</iconset>
                </property>
                <property name="iconSize">
                 <size>
                  <width>32</width>
                  <height>32</height>
                 </size>
                </property>
                <property name="checkable">
                 <bool>false</bool>
                </property>
                <property name="flat">
                 <bool>true</bool>
                </property>
               </widget>
              </item>
              <item row="0" column="2">
               <spacer name="horizontalSpacer">
                <property name="orientation">
                 <enum>Qt::Horizontal</enum>
                </property>
                <property name="sizeHint" stdset="0">
                 <size>
                  <width>40</width>
                  <height>20</height>
                 </size>
                </property>
               </spacer>
              </item>
              <item row="0" column="1">
               <widget class="QPushButton" name="m_PolygonButton">
                <property name="maximumSize">
                 <size>
                  <width>30</width>
                  <height>30</height>
                 </size>
                </property>
                <property name="toolTip">
                 <string>Draw polygonal ROI. Select reference fiber bundle to execute.</string>
                </property>
                <property name="text">
                 <string/>
                </property>
                <property name="icon">
                 <iconset resource="../../resources/QmitkDiffusionImaging.qrc">
                  <normaloff>:/QmitkDiffusionImaging/polygon.png</normaloff>:/QmitkDiffusionImaging/polygon.png</iconset>
                </property>
                <property name="iconSize">
                 <size>
                  <width>32</width>
                  <height>32</height>
                 </size>
                </property>
                <property name="checkable">
                 <bool>true</bool>
                </property>
                <property name="flat">
                 <bool>true</bool>
                </property>
               </widget>
              </item>
             </layout>
            </widget>
           </item>
          </layout>
         </widget>
        </item>
        <item row="0" column="0">
         <widget class="QComboBox" name="m_ExtractionMethodBox">
          <property name="sizePolicy">
           <sizepolicy hsizetype="Expanding" vsizetype="Fixed">
            <horstretch>0</horstretch>
            <verstretch>0</verstretch>
           </sizepolicy>
          </property>
          <item>
           <property name="text">
            <string>Extract using planar figures</string>
           </property>
          </item>
          <item>
           <property name="text">
            <string>Extract using binary ROI image</string>
           </property>
          </item>
         </widget>
        </item>
       </layout>
      </widget>
      <widget class="QWidget" name="page_3">
       <property name="geometry">
        <rect>
         <x>0</x>
         <y>0</y>
         <width>306</width>
         <height>410</height>
        </rect>
       </property>
       <attribute name="label">
        <string>Fiber Removal</string>
       </attribute>
       <attribute name="toolTip">
        <string>Remove fibers that satisfy certain criteria from the selected bundle.</string>
       </attribute>
       <layout class="QGridLayout" name="gridLayout_4">
        <item row="0" column="0">
         <widget class="QComboBox" name="m_RemovalMethodBox">
          <property name="sizePolicy">
           <sizepolicy hsizetype="Expanding" vsizetype="Fixed">
            <horstretch>0</horstretch>
            <verstretch>0</verstretch>
           </sizepolicy>
          </property>
          <item>
           <property name="text">
            <string>Remove fibers in direction</string>
           </property>
          </item>
          <item>
           <property name="text">
            <string>Remove fibers by length</string>
           </property>
          </item>
          <item>
           <property name="text">
            <string>Remove fibers by curvature</string>
           </property>
          </item>
          <item>
           <property name="text">
            <string>Remove fiber parts outside mask</string>
           </property>
          </item>
          <item>
           <property name="text">
            <string>Remove fiber parts inside mask</string>
           </property>
          </item>
         </widget>
        </item>
        <item row="2" column="0">
         <widget class="QFrame" name="m_RemoveLengthFrame">
          <property name="frameShape">
           <enum>QFrame::NoFrame</enum>
          </property>
          <property name="frameShadow">
           <enum>QFrame::Raised</enum>
          </property>
          <layout class="QGridLayout" name="gridLayout_6">
           <property name="leftMargin">
            <number>0</number>
           </property>
           <property name="topMargin">
            <number>0</number>
           </property>
           <property name="rightMargin">
            <number>0</number>
           </property>
           <property name="bottomMargin">
            <number>0</number>
           </property>
           <item row="0" column="2">
            <spacer name="horizontalSpacer_4">
             <property name="orientation">
              <enum>Qt::Horizontal</enum>
             </property>
             <property name="sizeHint" stdset="0">
              <size>
               <width>40</width>
               <height>20</height>
              </size>
             </property>
            </spacer>
           </item>
           <item row="0" column="1">
            <widget class="QSpinBox" name="m_PruneFibersMinBox">
             <property name="toolTip">
              <string>Minimum fiber length in mm</string>
             </property>
             <property name="minimum">
              <number>0</number>
             </property>
             <property name="maximum">
              <number>999999999</number>
             </property>
             <property name="value">
              <number>20</number>
             </property>
            </widget>
           </item>
           <item row="1" column="0">
            <widget class="QLabel" name="label_9">
             <property name="text">
              <string>Max. Length:</string>
             </property>
            </widget>
           </item>
           <item row="0" column="0">
            <widget class="QLabel" name="label_7">
             <property name="text">
              <string>Min. Length:</string>
             </property>
            </widget>
           </item>
           <item row="1" column="1">
            <widget class="QSpinBox" name="m_PruneFibersMaxBox">
             <property name="toolTip">
              <string>Maximum fiber length in mm</string>
             </property>
             <property name="minimum">
              <number>0</number>
             </property>
             <property name="maximum">
              <number>999999999</number>
             </property>
             <property name="value">
              <number>300</number>
             </property>
            </widget>
           </item>
          </layout>
         </widget>
        </item>
        <item row="1" column="0">
         <widget class="QFrame" name="m_RemoveDirectionFrame">
          <property name="frameShape">
           <enum>QFrame::NoFrame</enum>
          </property>
          <property name="frameShadow">
           <enum>QFrame::Raised</enum>
          </property>
          <layout class="QGridLayout" name="gridLayout_2">
           <property name="leftMargin">
            <number>0</number>
           </property>
           <property name="topMargin">
            <number>0</number>
           </property>
           <property name="rightMargin">
            <number>0</number>
           </property>
           <property name="bottomMargin">
            <number>0</number>
           </property>
           <property name="horizontalSpacing">
            <number>0</number>
           </property>
           <item row="0" column="0">
            <widget class="QLabel" name="label">
             <property name="text">
              <string>X:</string>
             </property>
            </widget>
           </item>
           <item row="1" column="0">
            <widget class="QLabel" name="label_3">
             <property name="text">
              <string>Y:</string>
             </property>
            </widget>
           </item>
           <item row="0" column="1">
            <widget class="QDoubleSpinBox" name="m_ExtractDirX"/>
           </item>
           <item row="1" column="1">
            <widget class="QDoubleSpinBox" name="m_ExtractDirY"/>
           </item>
           <item row="2" column="0">
            <widget class="QLabel" name="label_4">
             <property name="text">
              <string>Z:</string>
             </property>
            </widget>
           </item>
           <item row="2" column="1">
            <widget class="QDoubleSpinBox" name="m_ExtractDirZ"/>
           </item>
           <item row="3" column="0">
            <widget class="QLabel" name="label_5">
             <property name="text">
              <string>Angle:</string>
             </property>
            </widget>
           </item>
           <item row="3" column="1">
            <widget class="QDoubleSpinBox" name="m_ExtractAngle">
             <property name="toolTip">
              <string>Angular deviation threshold in degree</string>
             </property>
             <property name="decimals">
              <number>1</number>
             </property>
             <property name="maximum">
              <double>90.000000000000000</double>
             </property>
             <property name="singleStep">
              <double>1.000000000000000</double>
             </property>
             <property name="value">
              <double>5.000000000000000</double>
             </property>
            </widget>
           </item>
          </layout>
         </widget>
        </item>
        <item row="3" column="0">
         <widget class="QFrame" name="m_RemoveCurvatureFrame">
          <property name="frameShape">
           <enum>QFrame::NoFrame</enum>
          </property>
          <property name="frameShadow">
           <enum>QFrame::Raised</enum>
          </property>
          <layout class="QGridLayout" name="gridLayout_11">
           <property name="leftMargin">
            <number>0</number>
           </property>
           <property name="topMargin">
            <number>0</number>
           </property>
           <property name="rightMargin">
            <number>0</number>
           </property>
           <property name="bottomMargin">
            <number>0</number>
           </property>
           <item row="2" column="2">
            <widget class="QCheckBox" name="m_RemoveCurvedFibersBox">
             <property name="toolTip">
              <string>If unchecked, the fiber exceeding the threshold will be split in two instead of removed.</string>
             </property>
             <property name="text">
              <string>Remove Fiber</string>
             </property>
             <property name="checked">
              <bool>false</bool>
             </property>
            </widget>
           </item>
           <item row="1" column="2">
            <widget class="QFrame" name="frame">
             <property name="frameShape">
              <enum>QFrame::NoFrame</enum>
             </property>
             <property name="frameShadow">
              <enum>QFrame::Raised</enum>
             </property>
             <layout class="QGridLayout" name="gridLayout_12">
              <property name="leftMargin">
               <number>0</number>
              </property>
              <property name="topMargin">
               <number>0</number>
              </property>
              <property name="rightMargin">
               <number>0</number>
              </property>
              <property name="bottomMargin">
               <number>0</number>
              </property>
              <property name="verticalSpacing">
               <number>0</number>
              </property>
              <item row="0" column="0">
               <widget class="QLabel" name="label_8">
                <property name="text">
                 <string>Max. Angular Deviation:</string>
                </property>
               </widget>
              </item>
              <item row="0" column="2">
               <spacer name="horizontalSpacer_5">
                <property name="orientation">
                 <enum>Qt::Horizontal</enum>
                </property>
                <property name="sizeHint" stdset="0">
                 <size>
                  <width>40</width>
                  <height>20</height>
                 </size>
                </property>
               </spacer>
              </item>
              <item row="0" column="1">
               <widget class="QDoubleSpinBox" name="m_CurvSpinBox">
                <property name="toolTip">
                 <string>Maximum angular deviation in degree</string>
                </property>
                <property name="maximum">
                 <double>180.000000000000000</double>
                </property>
                <property name="singleStep">
                 <double>0.100000000000000</double>
                </property>
                <property name="value">
                 <double>30.000000000000000</double>
                </property>
               </widget>
              </item>
              <item row="1" column="0">
               <widget class="QLabel" name="label_14">
                <property name="text">
                 <string>Distance:</string>
                </property>
               </widget>
              </item>
              <item row="1" column="1">
               <widget class="QDoubleSpinBox" name="m_CurvDistanceSpinBox">
                <property name="toolTip">
                 <string>Distance in mm</string>
                </property>
                <property name="decimals">
                 <number>1</number>
                </property>
                <property name="maximum">
                 <double>999.000000000000000</double>
                </property>
                <property name="singleStep">
                 <double>1.000000000000000</double>
                </property>
                <property name="value">
                 <double>5.000000000000000</double>
                </property>
               </widget>
              </item>
             </layout>
            </widget>
           </item>
          </layout>
         </widget>
        </item>
        <item row="4" column="0">
         <widget class="QCommandLinkButton" name="m_RemoveButton">
          <property name="enabled">
           <bool>false</bool>
          </property>
          <property name="sizePolicy">
           <sizepolicy hsizetype="Preferred" vsizetype="Preferred">
            <horstretch>0</horstretch>
            <verstretch>0</verstretch>
           </sizepolicy>
          </property>
          <property name="maximumSize">
           <size>
            <width>200</width>
            <height>16777215</height>
           </size>
          </property>
          <property name="font">
           <font>
            <pointsize>11</pointsize>
           </font>
          </property>
          <property name="toolTip">
           <string/>
          </property>
          <property name="text">
           <string>Remove</string>
          </property>
         </widget>
        </item>
        <item row="5" column="0">
         <spacer name="verticalSpacer_4">
          <property name="orientation">
           <enum>Qt::Vertical</enum>
          </property>
          <property name="sizeHint" stdset="0">
           <size>
            <width>20</width>
            <height>40</height>
           </size>
          </property>
         </spacer>
        </item>
       </layout>
      </widget>
      <widget class="QWidget" name="page_4">
       <property name="geometry">
        <rect>
         <x>0</x>
         <y>0</y>
         <width>355</width>
         <height>382</height>
        </rect>
       </property>
       <attribute name="label">
        <string>Bundle Modification</string>
       </attribute>
       <attribute name="toolTip">
        <string>Modify the selected bundle with operations such as fiber resampling, FA coloring, etc.</string>
       </attribute>
       <layout class="QGridLayout" name="gridLayout_10">
        <item row="2" column="0">
         <widget class="QFrame" name="m_CompressFibersFrame">
          <property name="frameShape">
           <enum>QFrame::NoFrame</enum>
          </property>
          <property name="frameShadow">
           <enum>QFrame::Raised</enum>
          </property>
          <layout class="QGridLayout" name="gridLayout_15">
           <property name="leftMargin">
            <number>0</number>
           </property>
           <property name="topMargin">
            <number>0</number>
           </property>
           <property name="rightMargin">
            <number>0</number>
           </property>
           <property name="bottomMargin">
            <number>0</number>
           </property>
           <property name="spacing">
            <number>0</number>
           </property>
           <item row="0" column="0">
            <widget class="QLabel" name="label_10">
             <property name="text">
              <string>Error threshold in mm:</string>
             </property>
            </widget>
           </item>
           <item row="1" column="0">
            <widget class="QDoubleSpinBox" name="m_ErrorThresholdBox">
             <property name="maximum">
              <double>999999999.000000000000000</double>
             </property>
             <property name="singleStep">
              <double>0.100000000000000</double>
             </property>
             <property name="value">
              <double>0.100000000000000</double>
             </property>
            </widget>
           </item>
          </layout>
         </widget>
        </item>
        <item row="4" column="0">
         <widget class="QFrame" name="m_MirrorFibersFrame">
          <property name="frameShape">
           <enum>QFrame::NoFrame</enum>
          </property>
          <property name="frameShadow">
           <enum>QFrame::Raised</enum>
          </property>
          <layout class="QGridLayout" name="gridLayout_17">
           <property name="leftMargin">
            <number>0</number>
           </property>
           <property name="topMargin">
            <number>0</number>
           </property>
           <property name="rightMargin">
            <number>0</number>
           </property>
           <property name="bottomMargin">
            <number>0</number>
           </property>
           <property name="spacing">
            <number>0</number>
           </property>
           <item row="1" column="0">
            <widget class="QComboBox" name="m_MirrorFibersBox">
             <item>
              <property name="text">
-              <string>Axial</string>
+              <string>Sagittal</string>
              </property>
             </item>
             <item>
              <property name="text">
-              <string>Sagittal</string>
+              <string>Coronal</string>
              </property>
             </item>
             <item>
              <property name="text">
-              <string>Coronal</string>
+              <string>Axial</string>
              </property>
             </item>
            </widget>
           </item>
           <item row="0" column="0">
            <widget class="QLabel" name="label_13">
             <property name="text">
              <string>Select direction:</string>
             </property>
            </widget>
           </item>
          </layout>
         </widget>
        </item>
        <item row="3" column="0">
         <widget class="QFrame" name="m_ColorFibersFrame">
          <property name="frameShape">
           <enum>QFrame::NoFrame</enum>
          </property>
          <property name="frameShadow">
           <enum>QFrame::Raised</enum>
          </property>
          <layout class="QGridLayout" name="gridLayout_16">
           <property name="leftMargin">
            <number>0</number>
           </property>
           <property name="topMargin">
            <number>0</number>
           </property>
           <property name="rightMargin">
            <number>0</number>
           </property>
           <property name="bottomMargin">
            <number>0</number>
           </property>
           <property name="spacing">
            <number>0</number>
           </property>
           <item row="0" column="0">
            <widget class="QLabel" name="label_12">
             <property name="text">
              <string>Scalar map:</string>
             </property>
            </widget>
           </item>
           <item row="2" column="0">
            <widget class="QmitkDataStorageComboBox" name="m_ColorMapBox"/>
           </item>
           <item row="1" column="0">
            <widget class="QCheckBox" name="m_FiberOpacityBox">
             <property name="toolTip">
              <string>If checked, the image values are not only used to color the fibers but are also used as opaxity values.</string>
             </property>
             <property name="text">
              <string>Values as opacity</string>
             </property>
             <property name="checked">
              <bool>true</bool>
             </property>
            </widget>
           </item>
          </layout>
         </widget>
        </item>
        <item row="0" column="0">
         <widget class="QComboBox" name="m_ModificationMethodBox">
          <property name="sizePolicy">
           <sizepolicy hsizetype="Expanding" vsizetype="Fixed">
            <horstretch>0</horstretch>
            <verstretch>0</verstretch>
           </sizepolicy>
          </property>
          <item>
           <property name="text">
            <string>Smooth fibers</string>
           </property>
          </item>
          <item>
           <property name="text">
            <string>Compress fibers</string>
           </property>
          </item>
          <item>
           <property name="text">
            <string>Color fibers by scalar map (e.g. FA)</string>
           </property>
          </item>
          <item>
           <property name="text">
            <string>Mirror fibers</string>
           </property>
          </item>
          <item>
           <property name="text">
            <string>Weight Bundle</string>
           </property>
          </item>
          <item>
           <property name="text">
            <string>Color fibers by curvature</string>
           </property>
          </item>
         </widget>
        </item>
        <item row="1" column="0">
         <widget class="QFrame" name="m_SmoothFibersFrame">
          <property name="frameShape">
           <enum>QFrame::NoFrame</enum>
          </property>
          <property name="frameShadow">
           <enum>QFrame::Raised</enum>
          </property>
          <layout class="QGridLayout" name="gridLayout_7">
           <property name="leftMargin">
            <number>0</number>
           </property>
           <property name="topMargin">
            <number>0</number>
           </property>
           <property name="rightMargin">
            <number>0</number>
           </property>
           <property name="bottomMargin">
            <number>0</number>
           </property>
           <property name="spacing">
            <number>0</number>
           </property>
           <item row="1" column="0">
            <widget class="QDoubleSpinBox" name="m_SmoothFibersBox">
             <property name="minimum">
              <double>0.010000000000000</double>
             </property>
             <property name="maximum">
              <double>999999999.000000000000000</double>
             </property>
             <property name="value">
              <double>1.000000000000000</double>
             </property>
            </widget>
           </item>
           <item row="0" column="0">
            <widget class="QLabel" name="label_11">
             <property name="text">
              <string>Point distance in mm:</string>
             </property>
            </widget>
           </item>
          </layout>
         </widget>
        </item>
        <item row="7" column="0">
         <spacer name="verticalSpacer_3">
          <property name="orientation">
           <enum>Qt::Vertical</enum>
          </property>
          <property name="sizeHint" stdset="0">
           <size>
            <width>20</width>
            <height>40</height>
           </size>
          </property>
         </spacer>
        </item>
        <item row="6" column="0">
         <widget class="QCommandLinkButton" name="m_ModifyButton">
          <property name="enabled">
           <bool>false</bool>
          </property>
          <property name="sizePolicy">
           <sizepolicy hsizetype="Preferred" vsizetype="Preferred">
            <horstretch>0</horstretch>
            <verstretch>0</verstretch>
           </sizepolicy>
          </property>
          <property name="maximumSize">
           <size>
            <width>200</width>
            <height>16777215</height>
           </size>
          </property>
          <property name="font">
           <font>
            <pointsize>11</pointsize>
           </font>
          </property>
          <property name="toolTip">
           <string/>
          </property>
          <property name="text">
           <string>Execute</string>
          </property>
         </widget>
        </item>
        <item row="5" column="0">
         <widget class="QFrame" name="m_BundleWeightFrame">
          <property name="frameShape">
           <enum>QFrame::NoFrame</enum>
          </property>
          <property name="frameShadow">
           <enum>QFrame::Raised</enum>
          </property>
          <layout class="QGridLayout" name="gridLayout_18">
           <property name="leftMargin">
            <number>0</number>
           </property>
           <property name="topMargin">
            <number>0</number>
           </property>
           <property name="rightMargin">
            <number>0</number>
           </property>
           <property name="bottomMargin">
            <number>0</number>
           </property>
           <property name="spacing">
            <number>0</number>
           </property>
           <item row="0" column="0">
            <widget class="QLabel" name="label_15">
             <property name="text">
              <string>Weight:</string>
             </property>
            </widget>
           </item>
           <item row="0" column="1">
            <widget class="QDoubleSpinBox" name="m_BundleWeightBox">
             <property name="decimals">
              <number>7</number>
             </property>
             <property name="maximum">
-             <double>1.000000000000000</double>
+             <double>999999999.000000000000000</double>
             </property>
             <property name="singleStep">
              <double>0.100000000000000</double>
             </property>
             <property name="value">
              <double>1.000000000000000</double>
             </property>
            </widget>
           </item>
          </layout>
         </widget>
        </item>
       </layout>
      </widget>
      <widget class="QWidget" name="page_2">
       <property name="geometry">
        <rect>
         <x>0</x>
         <y>0</y>
         <width>360</width>
         <height>61</height>
        </rect>
       </property>
       <attribute name="label">
        <string>Binary Bundle Operations</string>
       </attribute>
       <attribute name="toolTip">
        <string>Join or subtract bundles.</string>
       </attribute>
       <layout class="QGridLayout" name="gridLayout_13">
        <item row="0" column="0">
         <widget class="QCommandLinkButton" name="m_SubstractBundles">
          <property name="enabled">
           <bool>false</bool>
          </property>
          <property name="sizePolicy">
           <sizepolicy hsizetype="Preferred" vsizetype="Preferred">
            <horstretch>0</horstretch>
            <verstretch>0</verstretch>
           </sizepolicy>
          </property>
          <property name="maximumSize">
           <size>
            <width>200</width>
            <height>16777215</height>
           </size>
          </property>
          <property name="font">
           <font>
            <pointsize>11</pointsize>
           </font>
          </property>
          <property name="toolTip">
           <string>Returns all fibers contained in bundle X that are not contained in bundle Y (not commutative!). Select at least two fiber bundles to execute.</string>
          </property>
          <property name="text">
           <string>Substract</string>
          </property>
         </widget>
        </item>
        <item row="0" column="2">
         <widget class="QCommandLinkButton" name="m_JoinBundles">
          <property name="enabled">
           <bool>false</bool>
          </property>
          <property name="sizePolicy">
           <sizepolicy hsizetype="Preferred" vsizetype="Preferred">
            <horstretch>0</horstretch>
            <verstretch>0</verstretch>
           </sizepolicy>
          </property>
          <property name="maximumSize">
           <size>
            <width>200</width>
            <height>16777215</height>
           </size>
          </property>
          <property name="font">
           <font>
            <pointsize>11</pointsize>
           </font>
          </property>
          <property name="toolTip">
           <string>Merge selected fiber bundles. Select at least two fiber bundles to execute.</string>
          </property>
          <property name="text">
           <string>Join</string>
          </property>
         </widget>
        </item>
        <item row="1" column="0">
         <spacer name="verticalSpacer_2">
          <property name="orientation">
           <enum>Qt::Vertical</enum>
          </property>
          <property name="sizeHint" stdset="0">
           <size>
            <width>20</width>
            <height>40</height>
           </size>
          </property>
         </spacer>
        </item>
       </layout>
      </widget>
     </widget>
    </item>
    <item row="0" column="0">
     <widget class="QGroupBox" name="m_InputData">
      <property name="title">
       <string>Please Select Input Data</string>
      </property>
      <layout class="QGridLayout" name="gridLayout_9">
       <item row="0" column="1">
        <widget class="QLabel" name="m_FibLabel">
         <property name="text">
          <string>&lt;html&gt;&lt;head/&gt;&lt;body&gt;&lt;p&gt;&lt;span style=&quot; color:#ff0000;&quot;&gt;mandatory&lt;/span&gt;&lt;/p&gt;&lt;/body&gt;&lt;/html&gt;</string>
         </property>
         <property name="wordWrap">
          <bool>true</bool>
         </property>
        </widget>
       </item>
       <item row="1" column="1">
        <widget class="QLabel" name="m_PfLabel">
         <property name="text">
          <string>&lt;html&gt;&lt;head/&gt;&lt;body&gt;&lt;p&gt;&lt;span style=&quot; color:#969696;&quot;&gt;needed for extraction&lt;/span&gt;&lt;/p&gt;&lt;/body&gt;&lt;/html&gt;</string>
         </property>
         <property name="wordWrap">
          <bool>true</bool>
         </property>
        </widget>
       </item>
       <item row="0" column="0">
        <widget class="QLabel" name="label_2">
         <property name="toolTip">
          <string>Input DTI</string>
         </property>
         <property name="text">
          <string>Fiber Bundle:</string>
         </property>
        </widget>
       </item>
       <item row="1" column="0">
        <widget class="QLabel" name="label_6">
         <property name="toolTip">
          <string>Binary seed ROI. If not specified, the whole image area is seeded.</string>
         </property>
         <property name="text">
          <string>ROI:</string>
         </property>
        </widget>
       </item>
      </layout>
     </widget>
    </item>
    <item row="3" column="0">
     <spacer name="verticalSpacer">
      <property name="orientation">
       <enum>Qt::Vertical</enum>
      </property>
      <property name="sizeHint" stdset="0">
       <size>
        <width>20</width>
        <height>40</height>
       </size>
      </property>
     </spacer>
    </item>
   </layout>
  </widget>
  <customwidgets>
   <customwidget>
    <class>QmitkDataStorageComboBox</class>
    <extends>QComboBox</extends>
    <header location="global">QmitkDataStorageComboBox.h</header>
   </customwidget>
  </customwidgets>
  <resources>
   <include location="../../resources/QmitkDiffusionImaging.qrc"/>
  </resources>
  <connections/>
 </ui>
diff --git a/Plugins/org.mitk.gui.qt.diffusionimaging/src/internal/QmitkFiberQuantificationView.cpp b/Plugins/org.mitk.gui.qt.diffusionimaging/src/internal/QmitkFiberQuantificationView.cpp
index 67114abb21..d2b5f86d5a 100644
--- a/Plugins/org.mitk.gui.qt.diffusionimaging/src/internal/QmitkFiberQuantificationView.cpp
+++ b/Plugins/org.mitk.gui.qt.diffusionimaging/src/internal/QmitkFiberQuantificationView.cpp
@@ -1,442 +1,455 @@
 /*===================================================================
 
 The Medical Imaging Interaction Toolkit (MITK)
 
 Copyright (c) German Cancer Research Center,
 Division of Medical and Biological Informatics.
 All rights reserved.
 
 This software is distributed WITHOUT ANY WARRANTY; without
 even the implied warranty of MERCHANTABILITY or FITNESS FOR
 A PARTICULAR PURPOSE.
 
 See LICENSE.txt or http://www.mitk.org for details.
 
 ===================================================================*/
 
 
 // Blueberry
 #include <berryISelectionService.h>
 #include <berryIWorkbenchWindow.h>
 
 // Qmitk
 #include "QmitkFiberQuantificationView.h"
 #include <QmitkStdMultiWidget.h>
 
 // Qt
 #include <QMessageBox>
 
 // MITK
 #include <mitkNodePredicateProperty.h>
 #include <mitkImageCast.h>
 #include <mitkPointSet.h>
 #include <mitkPlanarCircle.h>
 #include <mitkPlanarPolygon.h>
 #include <mitkPlanarRectangle.h>
 #include <mitkPlanarFigureInteractor.h>
 #include <mitkGlobalInteraction.h>
 #include <mitkImageAccessByItk.h>
 #include <mitkDataNodeObject.h>
 #include <mitkTensorImage.h>
 
 // ITK
 #include <itkResampleImageFilter.h>
 #include <itkGaussianInterpolateImageFunction.h>
 #include <itkImageRegionIteratorWithIndex.h>
 #include <itkTractsToFiberEndingsImageFilter.h>
 #include <itkTractDensityImageFilter.h>
 #include <itkImageRegion.h>
 #include <itkTractsToRgbaImageFilter.h>
 #include <itkTractsToVectorImageFilter.h>
 
 #include <math.h>
 #include <boost/lexical_cast.hpp>
 
 const std::string QmitkFiberQuantificationView::VIEW_ID = "org.mitk.views.fiberquantification";
 const std::string id_DataManager = "org.mitk.views.datamanager";
 using namespace mitk;
 
 QmitkFiberQuantificationView::QmitkFiberQuantificationView()
     : QmitkFunctionality()
     , m_Controls( 0 )
     , m_MultiWidget( NULL )
     , m_UpsamplingFactor(5)
 {
 
 }
 
 // Destructor
 QmitkFiberQuantificationView::~QmitkFiberQuantificationView()
 {
 
 }
 
 void QmitkFiberQuantificationView::CreateQtPartControl( QWidget *parent )
 {
     // build up qt view, unless already done
     if ( !m_Controls )
     {
         // create GUI widgets from the Qt Designer's .ui file
         m_Controls = new Ui::QmitkFiberQuantificationViewControls;
         m_Controls->setupUi( parent );
 
         connect( m_Controls->m_ProcessFiberBundleButton, SIGNAL(clicked()), this, SLOT(ProcessSelectedBundles()) );
         connect( m_Controls->m_ExtractFiberPeaks, SIGNAL(clicked()), this, SLOT(CalculateFiberDirections()) );
     }
 }
 
 void QmitkFiberQuantificationView::StdMultiWidgetAvailable (QmitkStdMultiWidget &stdMultiWidget)
 {
     m_MultiWidget = &stdMultiWidget;
 }
 
 
 void QmitkFiberQuantificationView::StdMultiWidgetNotAvailable()
 {
     m_MultiWidget = NULL;
 }
 
 void QmitkFiberQuantificationView::CalculateFiberDirections()
 {
     typedef itk::Image<unsigned char, 3>                                            ItkUcharImgType;
     typedef itk::Image< itk::Vector< float, 3>, 3 >                                 ItkDirectionImage3DType;
     typedef itk::VectorContainer< unsigned int, ItkDirectionImage3DType::Pointer >  ItkDirectionImageContainerType;
 
     // load fiber bundle
     mitk::FiberBundle::Pointer inputTractogram = dynamic_cast<mitk::FiberBundle*>(m_SelectedFB.back()->GetData());
 
     itk::TractsToVectorImageFilter<float>::Pointer fOdfFilter = itk::TractsToVectorImageFilter<float>::New();
     if (m_SelectedImage.IsNotNull())
     {
         ItkUcharImgType::Pointer itkMaskImage = ItkUcharImgType::New();
         mitk::CastToItkImage<ItkUcharImgType>(m_SelectedImage, itkMaskImage);
         fOdfFilter->SetMaskImage(itkMaskImage);
     }
 
     // extract directions from fiber bundle
     fOdfFilter->SetFiberBundle(inputTractogram);
     fOdfFilter->SetAngularThreshold(cos(m_Controls->m_AngularThreshold->value()*M_PI/180));
     fOdfFilter->SetNormalizeVectors(m_Controls->m_NormalizeDirectionsBox->isChecked());
     fOdfFilter->SetUseWorkingCopy(true);
     fOdfFilter->SetCreateDirectionImages(m_Controls->m_DirectionImagesBox->isChecked());
     fOdfFilter->SetSizeThreshold(m_Controls->m_PeakThreshold->value());
     fOdfFilter->SetMaxNumDirections(m_Controls->m_MaxNumDirections->value());
     fOdfFilter->Update();
 
     QString name = m_SelectedFB.back()->GetName().c_str();
 
     if (m_Controls->m_VectorFieldBox->isChecked())
     {
         float minSpacing = 1;
         if (m_SelectedImage.IsNotNull())
         {
             mitk::Vector3D outImageSpacing = m_SelectedImage->GetGeometry()->GetSpacing();
 
             if(outImageSpacing[0]<outImageSpacing[1] && outImageSpacing[0]<outImageSpacing[2])
                 minSpacing = outImageSpacing[0];
             else if (outImageSpacing[1] < outImageSpacing[2])
                 minSpacing = outImageSpacing[1];
             else
                 minSpacing = outImageSpacing[2];
         }
 
         mitk::FiberBundle::Pointer directions = fOdfFilter->GetOutputFiberBundle();
         mitk::DataNode::Pointer node = mitk::DataNode::New();
         node->SetData(directions);
         node->SetName((name+"_vectorfield").toStdString().c_str());
         node->SetProperty("Fiber2DSliceThickness", mitk::FloatProperty::New(minSpacing));
         node->SetProperty("Fiber2DfadeEFX", mitk::BoolProperty::New(false));
         node->SetProperty("color", mitk::ColorProperty::New(1.0f, 1.0f, 1.0f));
 
         GetDefaultDataStorage()->Add(node, m_SelectedFB.back());
     }
 
     if (m_Controls->m_NumDirectionsBox->isChecked())
     {
         mitk::Image::Pointer mitkImage = mitk::Image::New();
         mitkImage->InitializeByItk( fOdfFilter->GetNumDirectionsImage().GetPointer() );
         mitkImage->SetVolume( fOdfFilter->GetNumDirectionsImage()->GetBufferPointer() );
 
         mitk::DataNode::Pointer node = mitk::DataNode::New();
         node->SetData(mitkImage);
         node->SetName((name+"_numdirections").toStdString().c_str());
         GetDefaultDataStorage()->Add(node, m_SelectedFB.back());
     }
 
     if (m_Controls->m_DirectionImagesBox->isChecked())
     {
         ItkDirectionImageContainerType::Pointer directionImageContainer = fOdfFilter->GetDirectionImageContainer();
         for (unsigned int i=0; i<directionImageContainer->Size(); i++)
         {
             itk::TractsToVectorImageFilter<float>::ItkDirectionImageType::Pointer itkImg = directionImageContainer->GetElement(i);
 
             if (itkImg.IsNull())
                 return;
 
             mitk::Image::Pointer mitkImage = mitk::Image::New();
             mitkImage->InitializeByItk( itkImg.GetPointer() );
             mitkImage->SetVolume( itkImg->GetBufferPointer() );
 
             mitk::DataNode::Pointer node = mitk::DataNode::New();
             node->SetData(mitkImage);
             node->SetName( (name+"_direction_"+boost::lexical_cast<std::string>(i).c_str()).toStdString().c_str());
             node->SetVisibility(false);
             GetDefaultDataStorage()->Add(node, m_SelectedFB.back());
         }
     }
 }
 
 void QmitkFiberQuantificationView::UpdateGui()
 {
     m_Controls->m_ProcessFiberBundleButton->setEnabled(!m_SelectedFB.empty());
     m_Controls->m_ExtractFiberPeaks->setEnabled(!m_SelectedFB.empty());
 }
 
 void QmitkFiberQuantificationView::OnSelectionChanged( std::vector<mitk::DataNode*> nodes )
 {
     //reset existing Vectors containing FiberBundles and PlanarFigures from a previous selection
     m_SelectedFB.clear();
     m_SelectedSurfaces.clear();
     m_SelectedImage = NULL;
 
     for( std::vector<mitk::DataNode*>::iterator it = nodes.begin(); it != nodes.end(); ++it )
     {
         mitk::DataNode::Pointer node = *it;
         if ( dynamic_cast<mitk::FiberBundle*>(node->GetData()) )
         {
             m_SelectedFB.push_back(node);
         }
         else if (dynamic_cast<mitk::Image*>(node->GetData()))
             m_SelectedImage = dynamic_cast<mitk::Image*>(node->GetData());
         else if (dynamic_cast<mitk::Surface*>(node->GetData()))
         {
             m_SelectedSurfaces.push_back(dynamic_cast<mitk::Surface*>(node->GetData()));
         }
     }
     UpdateGui();
+
+
+    if (!this->IsVisible())
+        return;
     GenerateStats();
 }
 
 void QmitkFiberQuantificationView::Activated()
 {
 
 }
 
 void QmitkFiberQuantificationView::GenerateStats()
 {
     if ( m_SelectedFB.empty() )
         return;
 
     QString stats("");
 
     for( int i=0; i<m_SelectedFB.size(); i++ )
     {
         mitk::DataNode::Pointer node = m_SelectedFB[i];
         if (node.IsNotNull() && dynamic_cast<mitk::FiberBundle*>(node->GetData()))
         {
             if (i>0)
                 stats += "\n-----------------------------\n";
             stats += QString(node->GetName().c_str()) + "\n";
             mitk::FiberBundle::Pointer fib = dynamic_cast<mitk::FiberBundle*>(node->GetData());
             stats += "Number of fibers: "+ QString::number(fib->GetNumFibers()) + "\n";
             stats += "Number of points: "+ QString::number(fib->GetNumberOfPoints()) + "\n";
             stats += "Min. length:         "+ QString::number(fib->GetMinFiberLength(),'f',1) + " mm\n";
             stats += "Max. length:         "+ QString::number(fib->GetMaxFiberLength(),'f',1) + " mm\n";
             stats += "Mean length:         "+ QString::number(fib->GetMeanFiberLength(),'f',1) + " mm\n";
             stats += "Median length:       "+ QString::number(fib->GetMedianFiberLength(),'f',1) + " mm\n";
             stats += "Standard deviation:  "+ QString::number(fib->GetLengthStDev(),'f',1) + " mm\n";
         }
     }
     this->m_Controls->m_StatsTextEdit->setText(stats);
 }
 
 void QmitkFiberQuantificationView::ProcessSelectedBundles()
 {
     if ( m_SelectedFB.empty() ){
         QMessageBox::information( NULL, "Warning", "No fibe bundle selected!");
         MITK_WARN("QmitkFiberQuantificationView") << "no fibe bundle selected";
         return;
     }
 
     int generationMethod = m_Controls->m_GenerationBox->currentIndex();
 
     for( int i=0; i<m_SelectedFB.size(); i++ )
     {
         mitk::DataNode::Pointer node = m_SelectedFB[i];
         if (node.IsNotNull() && dynamic_cast<mitk::FiberBundle*>(node->GetData()))
         {
             mitk::FiberBundle::Pointer fib = dynamic_cast<mitk::FiberBundle*>(node->GetData());
             QString name(node->GetName().c_str());
             DataNode::Pointer newNode = NULL;
             switch(generationMethod){
             case 0:
                 newNode = GenerateTractDensityImage(fib, false, true);
                 name += "_TDI";
                 break;
             case 1:
                 newNode = GenerateTractDensityImage(fib, false, false);
                 name += "_TDI";
                 break;
             case 2:
                 newNode = GenerateTractDensityImage(fib, true, false);
                 name += "_envelope";
                 break;
             case 3:
                 newNode = GenerateColorHeatmap(fib);
                 break;
             case 4:
                 newNode = GenerateFiberEndingsImage(fib);
                 name += "_fiber_endings";
                 break;
             case 5:
                 newNode = GenerateFiberEndingsPointSet(fib);
                 name += "_fiber_endings";
                 break;
             }
             if (newNode.IsNotNull())
             {
                 newNode->SetName(name.toStdString());
                 GetDataStorage()->Add(newNode);
             }
         }
+        break;
     }
 }
 
 // generate pointset displaying the fiber endings
 mitk::DataNode::Pointer QmitkFiberQuantificationView::GenerateFiberEndingsPointSet(mitk::FiberBundle::Pointer fib)
 {
     mitk::PointSet::Pointer pointSet = mitk::PointSet::New();
     vtkSmartPointer<vtkPolyData> fiberPolyData = fib->GetFiberPolyData();
     vtkSmartPointer<vtkCellArray> vLines = fiberPolyData->GetLines();
     vLines->InitTraversal();
 
     int count = 0;
     int numFibers = fib->GetNumFibers();
     for( int i=0; i<numFibers; i++ )
     {
         vtkIdType   numPoints(0);
         vtkIdType*  points(NULL);
         vLines->GetNextCell ( numPoints, points );
 
         if (numPoints>0)
         {
             double* point = fiberPolyData->GetPoint(points[0]);
             itk::Point<float,3> itkPoint;
             itkPoint[0] = point[0];
             itkPoint[1] = point[1];
             itkPoint[2] = point[2];
             pointSet->InsertPoint(count, itkPoint);
             count++;
         }
         if (numPoints>2)
         {
             double* point = fiberPolyData->GetPoint(points[numPoints-1]);
             itk::Point<float,3> itkPoint;
             itkPoint[0] = point[0];
             itkPoint[1] = point[1];
             itkPoint[2] = point[2];
             pointSet->InsertPoint(count, itkPoint);
             count++;
         }
     }
 
     mitk::DataNode::Pointer node = mitk::DataNode::New();
     node->SetData( pointSet );
     return node;
 }
 
 // generate image displaying the fiber endings
 mitk::DataNode::Pointer QmitkFiberQuantificationView::GenerateFiberEndingsImage(mitk::FiberBundle::Pointer fib)
 {
     typedef unsigned char OutPixType;
     typedef itk::Image<OutPixType,3> OutImageType;
 
     typedef itk::TractsToFiberEndingsImageFilter< OutImageType > ImageGeneratorType;
     ImageGeneratorType::Pointer generator = ImageGeneratorType::New();
     generator->SetFiberBundle(fib);
     generator->SetUpsamplingFactor(m_Controls->m_UpsamplingSpinBox->value());
     if (m_SelectedImage.IsNotNull())
     {
         OutImageType::Pointer itkImage = OutImageType::New();
         CastToItkImage(m_SelectedImage, itkImage);
         generator->SetInputImage(itkImage);
         generator->SetUseImageGeometry(true);
     }
     generator->Update();
 
     // get output image
     OutImageType::Pointer outImg = generator->GetOutput();
     mitk::Image::Pointer img = mitk::Image::New();
     img->InitializeByItk(outImg.GetPointer());
     img->SetVolume(outImg->GetBufferPointer());
 
     // init data node
     mitk::DataNode::Pointer node = mitk::DataNode::New();
     node->SetData(img);
     return node;
 }
 
 // generate rgba heatmap from fiber bundle
 mitk::DataNode::Pointer QmitkFiberQuantificationView::GenerateColorHeatmap(mitk::FiberBundle::Pointer fib)
 {
     typedef itk::RGBAPixel<unsigned char> OutPixType;
     typedef itk::Image<OutPixType, 3> OutImageType;
     typedef itk::TractsToRgbaImageFilter< OutImageType > ImageGeneratorType;
     ImageGeneratorType::Pointer generator = ImageGeneratorType::New();
     generator->SetFiberBundle(fib);
     generator->SetUpsamplingFactor(m_Controls->m_UpsamplingSpinBox->value());
     if (m_SelectedImage.IsNotNull())
     {
         itk::Image<unsigned char, 3>::Pointer itkImage = itk::Image<unsigned char, 3>::New();
         CastToItkImage(m_SelectedImage, itkImage);
         generator->SetInputImage(itkImage);
         generator->SetUseImageGeometry(true);
     }
     generator->Update();
 
     // get output image
     typedef itk::Image<OutPixType,3> OutType;
     OutType::Pointer outImg = generator->GetOutput();
     mitk::Image::Pointer img = mitk::Image::New();
     img->InitializeByItk(outImg.GetPointer());
     img->SetVolume(outImg->GetBufferPointer());
 
     // init data node
     mitk::DataNode::Pointer node = mitk::DataNode::New();
     node->SetData(img);
     return node;
 }
 
 // generate tract density image from fiber bundle
 mitk::DataNode::Pointer QmitkFiberQuantificationView::GenerateTractDensityImage(mitk::FiberBundle::Pointer fib, bool binary, bool absolute)
 {
     typedef float OutPixType;
     typedef itk::Image<OutPixType, 3> OutImageType;
 
+    std::vector< mitk::FiberBundle::Pointer > fibs;
+    for (int i=0; i<m_SelectedFB.size(); i++)
+    {
+        mitk::FiberBundle::Pointer fib = dynamic_cast<mitk::FiberBundle*>(m_SelectedFB.at(i)->GetData());
+        fibs.push_back(fib);
+    }
+
     itk::TractDensityImageFilter< OutImageType >::Pointer generator = itk::TractDensityImageFilter< OutImageType >::New();
-    generator->SetFiberBundle(fib);
+    generator->fibs = fibs;
+//    generator->SetFiberBundle(fib);
     generator->SetBinaryOutput(binary);
     generator->SetOutputAbsoluteValues(absolute);
     generator->SetUpsamplingFactor(m_Controls->m_UpsamplingSpinBox->value());
     if (m_SelectedImage.IsNotNull())
     {
         OutImageType::Pointer itkImage = OutImageType::New();
         CastToItkImage(m_SelectedImage, itkImage);
         generator->SetInputImage(itkImage);
         generator->SetUseImageGeometry(true);
 
     }
     generator->Update();
 
     // get output image
     typedef itk::Image<OutPixType,3> OutType;
     OutType::Pointer outImg = generator->GetOutput();
     mitk::Image::Pointer img = mitk::Image::New();
     img->InitializeByItk(outImg.GetPointer());
     img->SetVolume(outImg->GetBufferPointer());
 
     // init data node
     mitk::DataNode::Pointer node = mitk::DataNode::New();
     node->SetData(img);
     return node;
 }
diff --git a/Plugins/org.mitk.gui.qt.diffusionimaging/src/internal/QmitkFiberfoxView.cpp b/Plugins/org.mitk.gui.qt.diffusionimaging/src/internal/QmitkFiberfoxView.cpp
index 547db4afeb..29adc20b94 100644
--- a/Plugins/org.mitk.gui.qt.diffusionimaging/src/internal/QmitkFiberfoxView.cpp
+++ b/Plugins/org.mitk.gui.qt.diffusionimaging/src/internal/QmitkFiberfoxView.cpp
@@ -1,2695 +1,2702 @@
 /*===================================================================
 
 The Medical Imaging Interaction Toolkit (MITK)
 
 Copyright (c) German Cancer Research Center,
 Division of Medical and Biological Informatics.
 All rights reserved.
 
 This software is distributed WITHOUT ANY WARRANTY; without
 even the implied warranty of MERCHANTABILITY or FITNESS FOR
 A PARTICULAR PURPOSE.
 
 See LICENSE.txt or http://www.mitk.org for details.
 
 ===================================================================*/
 
 //misc
 #define _USE_MATH_DEFINES
 #include <math.h>
 
 // Blueberry
 #include <berryISelectionService.h>
 #include <berryIWorkbenchWindow.h>
 
 // Qmitk
 #include "QmitkFiberfoxView.h"
 
 // MITK
 #include <mitkImage.h>
 #include <mitkImageToItk.h>
 #include <mitkImageCast.h>
 #include <mitkProperties.h>
 #include <mitkPlanarFigureInteractor.h>
 #include <mitkDataStorage.h>
 #include <itkFibersFromPlanarFiguresFilter.h>
 #include <itkTractsToDWIImageFilter.h>
 #include <mitkTensorImage.h>
 #include <mitkILinkedRenderWindowPart.h>
 #include <mitkGlobalInteraction.h>
 #include <mitkImageToItk.h>
 #include <mitkImageCast.h>
 #include <mitkImageGenerator.h>
 #include <mitkNodePredicateDataType.h>
 #include <itkScalableAffineTransform.h>
 #include <mitkLevelWindowProperty.h>
 #include <mitkNodePredicateOr.h>
 #include <mitkNodePredicateAnd.h>
 #include <mitkNodePredicateNot.h>
 #include <mitkNodePredicateProperty.h>
 #include <mitkNodePredicateIsDWI.h>
 #include <boost/property_tree/ptree.hpp>
 #include <boost/property_tree/xml_parser.hpp>
 #include <boost/foreach.hpp>
 #include <QFileDialog>
 #include <QMessageBox>
 #include "usModuleRegistry.h"
 #include <mitkChiSquareNoiseModel.h>
 #include <itksys/SystemTools.hxx>
 #include <mitkIOUtil.h>
 #include <QScrollBar>
 #include <itkInvertIntensityImageFilter.h>
 #include <QDialogButtonBox>
 #include <itkAdcImageFilter.h>
 #include <itkShiftScaleImageFilter.h>
 #include <mitkITKImageImport.h>
 
 #include "mitkNodePredicateDataType.h"
 #include <mitkNodePredicateProperty.h>
 #include <mitkNodePredicateAnd.h>
 #include <mitkNodePredicateNot.h>
 #include <mitkNodePredicateOr.h>
 
 #define _USE_MATH_DEFINES
 #include <math.h>
 
 QmitkFiberfoxWorker::QmitkFiberfoxWorker(QmitkFiberfoxView* view)
     : m_View(view)
 {
 
 }
 
 void QmitkFiberfoxWorker::run()
 {
     try{
         switch (m_FilterType)
         {
         case 0:
             m_View->m_TractsToDwiFilter->Update();
             break;
         case 1:
             m_View->m_ArtifactsToDwiFilter->Update();
             break;
         }
     }
     catch( ... )
     {
 
     }
     m_View->m_Thread.quit();
 }
 
 const std::string QmitkFiberfoxView::VIEW_ID = "org.mitk.views.fiberfoxview";
 
 QmitkFiberfoxView::QmitkFiberfoxView()
     : QmitkAbstractView()
     , m_Controls( 0 )
-    , m_SelectedImage( NULL )
+    , m_SelectedImageNode( NULL )
     , m_Worker(this)
     , m_ThreadIsRunning(false)
 {
     m_Worker.moveToThread(&m_Thread);
     connect(&m_Thread, SIGNAL(started()), this, SLOT(BeforeThread()));
     connect(&m_Thread, SIGNAL(started()), &m_Worker, SLOT(run()));
     connect(&m_Thread, SIGNAL(finished()), this, SLOT(AfterThread()));
     connect(&m_Thread, SIGNAL(terminated()), this, SLOT(AfterThread()));
     m_SimulationTimer = new QTimer(this);
 }
 
 void QmitkFiberfoxView::KillThread()
 {
     MITK_INFO << "Aborting DWI simulation.";
     switch (m_Worker.m_FilterType)
     {
     case 0:
         m_TractsToDwiFilter->SetAbortGenerateData(true);
         break;
     case 1:
         m_ArtifactsToDwiFilter->SetAbortGenerateData(true);
         break;
     }
     m_Controls->m_AbortSimulationButton->setEnabled(false);
     m_Controls->m_AbortSimulationButton->setText("Aborting simulation ...");
 }
 
 void QmitkFiberfoxView::BeforeThread()
 {
     m_SimulationTime = QTime::currentTime();
     m_SimulationTimer->start(100);
     m_Controls->m_AbortSimulationButton->setVisible(true);
     m_Controls->m_GenerateImageButton->setVisible(false);
     m_Controls->m_SimulationStatusText->setVisible(true);
     m_ThreadIsRunning = true;
 }
 
 void QmitkFiberfoxView::AfterThread()
 {
     UpdateSimulationStatus();
     m_SimulationTimer->stop();
     m_Controls->m_AbortSimulationButton->setVisible(false);
     m_Controls->m_AbortSimulationButton->setEnabled(true);
     m_Controls->m_AbortSimulationButton->setText("Abort simulation");
     m_Controls->m_GenerateImageButton->setVisible(true);
     m_ThreadIsRunning = false;
 
     QString statusText;
     FiberfoxParameters<double> parameters;
     mitk::Image::Pointer mitkImage = mitk::Image::New();
     switch (m_Worker.m_FilterType)
     {
     case 0:
     {
         statusText = QString(m_TractsToDwiFilter->GetStatusText().c_str());
         if (m_TractsToDwiFilter->GetAbortGenerateData())
         {
             MITK_INFO << "Simulation aborted.";
             return;
         }
 
         parameters = m_TractsToDwiFilter->GetParameters();
 
         mitkImage = mitk::GrabItkImageMemory( m_TractsToDwiFilter->GetOutput() );
         mitkImage->SetProperty( mitk::DiffusionPropertyHelper::GRADIENTCONTAINERPROPERTYNAME.c_str(), mitk::GradientDirectionsProperty::New(  parameters.m_SignalGen.GetGradientDirections()  ));
         mitkImage->SetProperty( mitk::DiffusionPropertyHelper::REFERENCEBVALUEPROPERTYNAME.c_str(), mitk::FloatProperty::New( parameters.m_SignalGen.m_Bvalue ));
         mitk::DiffusionPropertyHelper propertyHelper( mitkImage );
         propertyHelper.InitializeImage();
         parameters.m_Misc.m_ResultNode->SetData( mitkImage );
 
         parameters.m_Misc.m_ResultNode->SetName(parameters.m_Misc.m_ParentNode->GetName()
                                                 +"_D"+QString::number(parameters.m_SignalGen.m_ImageRegion.GetSize(0)).toStdString()
                                                 +"-"+QString::number(parameters.m_SignalGen.m_ImageRegion.GetSize(1)).toStdString()
                                                 +"-"+QString::number(parameters.m_SignalGen.m_ImageRegion.GetSize(2)).toStdString()
                                                 +"_S"+QString::number(parameters.m_SignalGen.m_ImageSpacing[0]).toStdString()
                 +"-"+QString::number(parameters.m_SignalGen.m_ImageSpacing[1]).toStdString()
                 +"-"+QString::number(parameters.m_SignalGen.m_ImageSpacing[2]).toStdString()
                 +"_b"+QString::number(parameters.m_SignalGen.m_Bvalue).toStdString()
                 +"_"+parameters.m_Misc.m_SignalModelString
                 +parameters.m_Misc.m_ArtifactModelString);
 
         GetDataStorage()->Add(parameters.m_Misc.m_ResultNode, parameters.m_Misc.m_ParentNode);
 
         parameters.m_Misc.m_ResultNode->SetProperty( "levelwindow", mitk::LevelWindowProperty::New(m_TractsToDwiFilter->GetLevelWindow()) );
 
         if (m_Controls->m_VolumeFractionsBox->isChecked())
         {
             std::vector< itk::TractsToDWIImageFilter< short >::ItkDoubleImgType::Pointer > volumeFractions = m_TractsToDwiFilter->GetVolumeFractions();
             for (unsigned int k=0; k<volumeFractions.size(); k++)
             {
                 mitk::Image::Pointer image = mitk::Image::New();
                 image->InitializeByItk(volumeFractions.at(k).GetPointer());
                 image->SetVolume(volumeFractions.at(k)->GetBufferPointer());
 
                 mitk::DataNode::Pointer node = mitk::DataNode::New();
                 node->SetData( image );
                 node->SetName(parameters.m_Misc.m_ParentNode->GetName()+"_CompartmentVolume-"+QString::number(k).toStdString());
                 GetDataStorage()->Add(node, parameters.m_Misc.m_ParentNode);
             }
         }
         m_TractsToDwiFilter = NULL;
         break;
     }
     case 1:
     {
         statusText = QString(m_ArtifactsToDwiFilter->GetStatusText().c_str());
         if (m_ArtifactsToDwiFilter->GetAbortGenerateData())
         {
             MITK_INFO << "Simulation aborted.";
             return;
         }
 
         parameters = m_ArtifactsToDwiFilter->GetParameters().CopyParameters<double>();
 
         mitk::Image::Pointer diffImg = dynamic_cast<mitk::Image*>(parameters.m_Misc.m_ParentNode->GetData());
         mitkImage = mitk::GrabItkImageMemory( m_ArtifactsToDwiFilter->GetOutput() );
 
         mitkImage->SetProperty( mitk::DiffusionPropertyHelper::GRADIENTCONTAINERPROPERTYNAME.c_str(), mitk::GradientDirectionsProperty::New( static_cast<mitk::GradientDirectionsProperty*>( diffImg->GetProperty(mitk::DiffusionPropertyHelper::GRADIENTCONTAINERPROPERTYNAME.c_str()).GetPointer() )->GetGradientDirectionsContainer() ) );
         mitkImage->SetProperty( mitk::DiffusionPropertyHelper::REFERENCEBVALUEPROPERTYNAME.c_str(), mitk::FloatProperty::New( static_cast<mitk::FloatProperty*>( diffImg->GetProperty(mitk::DiffusionPropertyHelper::REFERENCEBVALUEPROPERTYNAME.c_str()).GetPointer() )->GetValue() ) );
         mitk::DiffusionPropertyHelper propertyHelper( mitkImage );
         propertyHelper.InitializeImage();
 
         parameters.m_Misc.m_ResultNode->SetData( mitkImage );
         parameters.m_Misc.m_ResultNode->SetName(parameters.m_Misc.m_ParentNode->GetName()+parameters.m_Misc.m_ArtifactModelString);
         GetDataStorage()->Add(parameters.m_Misc.m_ResultNode, parameters.m_Misc.m_ParentNode);
         m_ArtifactsToDwiFilter = NULL;
         break;
     }
     }
 
     mitk::BaseData::Pointer basedata = parameters.m_Misc.m_ResultNode->GetData();
     if (basedata.IsNotNull())
     {
         mitk::RenderingManager::GetInstance()->InitializeViews(
                     basedata->GetTimeGeometry(), mitk::RenderingManager::REQUEST_UPDATE_ALL, true );
         mitk::RenderingManager::GetInstance()->RequestUpdateAll();
     }
 
     if (!parameters.m_Misc.m_OutputPath.empty())
     {
         try{
             QString outputFileName(parameters.m_Misc.m_OutputPath.c_str());
             outputFileName += parameters.m_Misc.m_ResultNode->GetName().c_str();
             outputFileName.replace(QString("."), QString("_"));
             outputFileName += ".dwi";
             QString status("Saving output image to ");
             status += outputFileName;
             m_Controls->m_SimulationStatusText->append(status);
             mitk::IOUtil::SaveBaseData(mitkImage, outputFileName.toStdString());
             m_Controls->m_SimulationStatusText->append("File saved successfully.");
         }
         catch (itk::ExceptionObject &e)
         {
             QString status("Exception during DWI writing: ");
             status += e.GetDescription();
             m_Controls->m_SimulationStatusText->append(status);
         }
         catch (...)
         {
             m_Controls->m_SimulationStatusText->append("Unknown exception during DWI writing!");
         }
     }
     parameters.m_SignalGen.m_FrequencyMap = NULL;
 }
 
 void QmitkFiberfoxView::UpdateSimulationStatus()
 {
     QString statusText;
     switch (m_Worker.m_FilterType)
     {
     case 0:
         statusText = QString(m_TractsToDwiFilter->GetStatusText().c_str());
         break;
     case 1:
         statusText = QString(m_ArtifactsToDwiFilter->GetStatusText().c_str());
         break;
     }
 
     if (QString::compare(m_SimulationStatusText,statusText)!=0)
     {
         m_Controls->m_SimulationStatusText->clear();
         statusText = "<pre>"+statusText+"</pre>";
         m_Controls->m_SimulationStatusText->setText(statusText);
         QScrollBar *vScrollBar = m_Controls->m_SimulationStatusText->verticalScrollBar();
         vScrollBar->triggerAction(QScrollBar::SliderToMaximum);
     }
 }
 
 // Destructor
 QmitkFiberfoxView::~QmitkFiberfoxView()
 {
     delete m_SimulationTimer;
 }
 
 void QmitkFiberfoxView::CreateQtPartControl( QWidget *parent )
 {
     // build up qt view, unless already done
     if ( !m_Controls )
     {
         // create GUI widgets from the Qt Designer's .ui file
         m_Controls = new Ui::QmitkFiberfoxViewControls;
         m_Controls->setupUi( parent );
 
         // commented out
         m_Controls->m_DiffusionDirectionBox->setVisible(false);
         m_Controls->label_3->setVisible(false);
         m_Controls->m_SeparationAngleBox->setVisible(false);
         m_Controls->label_4->setVisible(false);
         //
 
         m_Controls->m_StickWidget1->setVisible(true);
         m_Controls->m_StickWidget2->setVisible(false);
         m_Controls->m_ZeppelinWidget1->setVisible(false);
         m_Controls->m_ZeppelinWidget2->setVisible(false);
         m_Controls->m_TensorWidget1->setVisible(false);
         m_Controls->m_TensorWidget2->setVisible(false);
 
         m_Controls->m_BallWidget1->setVisible(true);
         m_Controls->m_BallWidget2->setVisible(false);
         m_Controls->m_AstrosticksWidget1->setVisible(false);
         m_Controls->m_AstrosticksWidget2->setVisible(false);
         m_Controls->m_DotWidget1->setVisible(false);
         m_Controls->m_DotWidget2->setVisible(false);
 
         m_Controls->m_PrototypeWidget1->setVisible(false);
         m_Controls->m_PrototypeWidget2->setVisible(false);
         m_Controls->m_PrototypeWidget3->setVisible(false);
         m_Controls->m_PrototypeWidget4->setVisible(false);
 
         m_Controls->m_PrototypeWidget3->SetMinFa(0.0);
         m_Controls->m_PrototypeWidget3->SetMaxFa(0.15);
         m_Controls->m_PrototypeWidget4->SetMinFa(0.0);
         m_Controls->m_PrototypeWidget4->SetMaxFa(0.15);
         m_Controls->m_PrototypeWidget3->SetMinAdc(0.0);
         m_Controls->m_PrototypeWidget3->SetMaxAdc(0.001);
         m_Controls->m_PrototypeWidget4->SetMinAdc(0.003);
         m_Controls->m_PrototypeWidget4->SetMaxAdc(0.004);
 
         m_Controls->m_Comp4FractionFrame->setVisible(false);
         m_Controls->m_DiffusionPropsMessage->setVisible(false);
         m_Controls->m_GeometryMessage->setVisible(false);
         m_Controls->m_AdvancedSignalOptionsFrame->setVisible(false);
         m_Controls->m_AdvancedFiberOptionsFrame->setVisible(false);
         m_Controls->m_VarianceBox->setVisible(false);
         m_Controls->m_NoiseFrame->setVisible(false);
         m_Controls->m_GhostFrame->setVisible(false);
         m_Controls->m_DistortionsFrame->setVisible(false);
         m_Controls->m_EddyFrame->setVisible(false);
         m_Controls->m_SpikeFrame->setVisible(false);
         m_Controls->m_AliasingFrame->setVisible(false);
         m_Controls->m_MotionArtifactFrame->setVisible(false);
         m_ParameterFile = QDir::currentPath()+"/param.ffp";
 
         m_Controls->m_AbortSimulationButton->setVisible(false);
         m_Controls->m_SimulationStatusText->setVisible(false);
 
         m_Controls->m_FrequencyMapBox->SetDataStorage(this->GetDataStorage());
         m_Controls->m_Comp4VolumeFraction->SetDataStorage(this->GetDataStorage());
         m_Controls->m_MaskComboBox->SetDataStorage(this->GetDataStorage());
         m_Controls->m_TemplateComboBox->SetDataStorage(this->GetDataStorage());
         m_Controls->m_FiberBundleComboBox->SetDataStorage(this->GetDataStorage());
 
         mitk::TNodePredicateDataType<mitk::FiberBundle>::Pointer isFiberBundle = mitk::TNodePredicateDataType<mitk::FiberBundle>::New();
         mitk::TNodePredicateDataType<mitk::Image>::Pointer isMitkImage = mitk::TNodePredicateDataType<mitk::Image>::New();
         mitk::NodePredicateIsDWI::Pointer isDwi = mitk::NodePredicateIsDWI::New( );
         mitk::NodePredicateDataType::Pointer isDti = mitk::NodePredicateDataType::New("TensorImage");
         mitk::NodePredicateDataType::Pointer isQbi = mitk::NodePredicateDataType::New("QBallImage");
         mitk::NodePredicateOr::Pointer isDiffusionImage = mitk::NodePredicateOr::New(isDwi, isDti);
         isDiffusionImage = mitk::NodePredicateOr::New(isDiffusionImage, isQbi);
         mitk::NodePredicateNot::Pointer noDiffusionImage = mitk::NodePredicateNot::New(isDiffusionImage);
         mitk::NodePredicateAnd::Pointer isNonDiffMitkImage = mitk::NodePredicateAnd::New(isMitkImage, noDiffusionImage);
         mitk::NodePredicateProperty::Pointer isBinaryPredicate = mitk::NodePredicateProperty::New("binary", mitk::BoolProperty::New(true));
         mitk::NodePredicateAnd::Pointer isBinaryMitkImage = mitk::NodePredicateAnd::New( isNonDiffMitkImage, isBinaryPredicate );
 
         m_Controls->m_FrequencyMapBox->SetPredicate(isNonDiffMitkImage);
         m_Controls->m_Comp4VolumeFraction->SetPredicate(isNonDiffMitkImage);
         m_Controls->m_MaskComboBox->SetPredicate(isBinaryMitkImage);
         m_Controls->m_MaskComboBox->SetZeroEntryText("--");
         m_Controls->m_TemplateComboBox->SetPredicate(isMitkImage);
         m_Controls->m_TemplateComboBox->SetZeroEntryText("--");
         m_Controls->m_FiberBundleComboBox->SetPredicate(isFiberBundle);
         m_Controls->m_FiberBundleComboBox->SetZeroEntryText("--");
 
 //        mitk::NodePredicateDimension::Pointer dimensionPredicate = mitk::NodePredicateDimension::New(3);
 
         connect( m_SimulationTimer, SIGNAL(timeout()), this, SLOT(UpdateSimulationStatus()) );
         connect((QObject*) m_Controls->m_AbortSimulationButton, SIGNAL(clicked()), (QObject*) this, SLOT(KillThread()));
         connect((QObject*) m_Controls->m_GenerateImageButton, SIGNAL(clicked()), (QObject*) this, SLOT(GenerateImage()));
         connect((QObject*) m_Controls->m_GenerateFibersButton, SIGNAL(clicked()), (QObject*) this, SLOT(GenerateFibers()));
         connect((QObject*) m_Controls->m_CircleButton, SIGNAL(clicked()), (QObject*) this, SLOT(OnDrawROI()));
         connect((QObject*) m_Controls->m_FlipButton, SIGNAL(clicked()), (QObject*) this, SLOT(OnFlipButton()));
         connect((QObject*) m_Controls->m_JoinBundlesButton, SIGNAL(clicked()), (QObject*) this, SLOT(JoinBundles()));
         connect((QObject*) m_Controls->m_VarianceBox, SIGNAL(valueChanged(double)), (QObject*) this, SLOT(OnVarianceChanged(double)));
         connect((QObject*) m_Controls->m_DistributionBox, SIGNAL(currentIndexChanged(int)), (QObject*) this, SLOT(OnDistributionChanged(int)));
         connect((QObject*) m_Controls->m_FiberDensityBox, SIGNAL(valueChanged(int)), (QObject*) this, SLOT(OnFiberDensityChanged(int)));
         connect((QObject*) m_Controls->m_FiberSamplingBox, SIGNAL(valueChanged(double)), (QObject*) this, SLOT(OnFiberSamplingChanged(double)));
         connect((QObject*) m_Controls->m_TensionBox, SIGNAL(valueChanged(double)), (QObject*) this, SLOT(OnTensionChanged(double)));
         connect((QObject*) m_Controls->m_ContinuityBox, SIGNAL(valueChanged(double)), (QObject*) this, SLOT(OnContinuityChanged(double)));
         connect((QObject*) m_Controls->m_BiasBox, SIGNAL(valueChanged(double)), (QObject*) this, SLOT(OnBiasChanged(double)));
         connect((QObject*) m_Controls->m_AddNoise, SIGNAL(stateChanged(int)), (QObject*) this, SLOT(OnAddNoise(int)));
         connect((QObject*) m_Controls->m_AddGhosts, SIGNAL(stateChanged(int)), (QObject*) this, SLOT(OnAddGhosts(int)));
         connect((QObject*) m_Controls->m_AddDistortions, SIGNAL(stateChanged(int)), (QObject*) this, SLOT(OnAddDistortions(int)));
         connect((QObject*) m_Controls->m_AddEddy, SIGNAL(stateChanged(int)), (QObject*) this, SLOT(OnAddEddy(int)));
         connect((QObject*) m_Controls->m_AddSpikes, SIGNAL(stateChanged(int)), (QObject*) this, SLOT(OnAddSpikes(int)));
         connect((QObject*) m_Controls->m_AddAliasing, SIGNAL(stateChanged(int)), (QObject*) this, SLOT(OnAddAliasing(int)));
         connect((QObject*) m_Controls->m_AddMotion, SIGNAL(stateChanged(int)), (QObject*) this, SLOT(OnAddMotion(int)));
 
         connect((QObject*) m_Controls->m_ConstantRadiusBox, SIGNAL(stateChanged(int)), (QObject*) this, SLOT(OnConstantRadius(int)));
         connect((QObject*) m_Controls->m_CopyBundlesButton, SIGNAL(clicked()), (QObject*) this, SLOT(CopyBundles()));
         connect((QObject*) m_Controls->m_TransformBundlesButton, SIGNAL(clicked()), (QObject*) this, SLOT(ApplyTransform()));
         connect((QObject*) m_Controls->m_AlignOnGrid, SIGNAL(clicked()), (QObject*) this, SLOT(AlignOnGrid()));
 
         connect((QObject*) m_Controls->m_Compartment1Box, SIGNAL(currentIndexChanged(int)), (QObject*) this, SLOT(Comp1ModelFrameVisibility(int)));
         connect((QObject*) m_Controls->m_Compartment2Box, SIGNAL(currentIndexChanged(int)), (QObject*) this, SLOT(Comp2ModelFrameVisibility(int)));
         connect((QObject*) m_Controls->m_Compartment3Box, SIGNAL(currentIndexChanged(int)), (QObject*) this, SLOT(Comp3ModelFrameVisibility(int)));
         connect((QObject*) m_Controls->m_Compartment4Box, SIGNAL(currentIndexChanged(int)), (QObject*) this, SLOT(Comp4ModelFrameVisibility(int)));
 
         connect((QObject*) m_Controls->m_AdvancedOptionsBox, SIGNAL( stateChanged(int)), (QObject*) this, SLOT(ShowAdvancedOptions(int)));
         connect((QObject*) m_Controls->m_AdvancedOptionsBox_2, SIGNAL( stateChanged(int)), (QObject*) this, SLOT(ShowAdvancedOptions(int)));
 
         connect((QObject*) m_Controls->m_SaveParametersButton, SIGNAL(clicked()), (QObject*) this, SLOT(SaveParameters()));
         connect((QObject*) m_Controls->m_LoadParametersButton, SIGNAL(clicked()), (QObject*) this, SLOT(LoadParameters()));
         connect((QObject*) m_Controls->m_OutputPathButton, SIGNAL(clicked()), (QObject*) this, SLOT(SetOutputPath()));
 
         connect((QObject*) m_Controls->m_MaskComboBox, SIGNAL(currentIndexChanged(int)), (QObject*) this, SLOT(OnMaskSelected(int)));
         connect((QObject*) m_Controls->m_TemplateComboBox, SIGNAL(currentIndexChanged(int)), (QObject*) this, SLOT(OnTemplateSelected(int)));
         connect((QObject*) m_Controls->m_FiberBundleComboBox, SIGNAL(currentIndexChanged(int)), (QObject*) this, SLOT(OnFibSelected(int)));
     }
 }
 
 void QmitkFiberfoxView::OnMaskSelected(int value)
 {
     UpdateGui();
 }
 
 void QmitkFiberfoxView::OnTemplateSelected(int value)
 {
     UpdateGui();
 }
 
 void QmitkFiberfoxView::OnFibSelected(int value)
 {
     UpdateGui();
 }
 
 template< class ScalarType >
 FiberfoxParameters< ScalarType > QmitkFiberfoxView::UpdateImageParameters()
 {
     FiberfoxParameters< ScalarType > parameters;
     parameters.m_Misc.m_OutputPath = "";
     parameters.m_Misc.m_CheckAdvancedFiberOptionsBox = m_Controls->m_AdvancedOptionsBox->isChecked();
     parameters.m_Misc.m_CheckAdvancedSignalOptionsBox = m_Controls->m_AdvancedOptionsBox_2->isChecked();
     parameters.m_Misc.m_CheckOutputVolumeFractionsBox = m_Controls->m_VolumeFractionsBox->isChecked();
 
     string outputPath = m_Controls->m_SavePathEdit->text().toStdString();
     if (outputPath.compare("-")!=0)
     {
         parameters.m_Misc.m_OutputPath = outputPath;
         parameters.m_Misc.m_OutputPath += "/";
     }
 
     if (m_Controls->m_MaskComboBox->GetSelectedNode().IsNotNull())
     {
         mitk::Image::Pointer mitkMaskImage = dynamic_cast<mitk::Image*>(m_Controls->m_MaskComboBox->GetSelectedNode()->GetData());
         mitk::CastToItkImage<ItkUcharImgType>(mitkMaskImage, parameters.m_SignalGen.m_MaskImage);
         itk::ImageDuplicator<ItkUcharImgType>::Pointer duplicator = itk::ImageDuplicator<ItkUcharImgType>::New();
         duplicator->SetInputImage(parameters.m_SignalGen.m_MaskImage);
         duplicator->Update();
         parameters.m_SignalGen.m_MaskImage = duplicator->GetOutput();
     }
 
     if (m_Controls->m_TemplateComboBox->GetSelectedNode().IsNotNull() && mitk::DiffusionPropertyHelper::IsDiffusionWeightedImage( dynamic_cast<mitk::Image*>(m_Controls->m_TemplateComboBox->GetSelectedNode()->GetData())))  // use parameters of selected DWI
     {
         mitk::Image::Pointer dwi = dynamic_cast<mitk::Image*>(m_Controls->m_TemplateComboBox->GetSelectedNode()->GetData());
 
         ItkDwiType::Pointer itkVectorImagePointer = ItkDwiType::New();
         mitk::CastToItkImage(dwi, itkVectorImagePointer);
 
         parameters.m_SignalGen.m_ImageRegion = itkVectorImagePointer->GetLargestPossibleRegion();
         parameters.m_SignalGen.m_ImageSpacing = itkVectorImagePointer->GetSpacing();
         parameters.m_SignalGen.m_ImageOrigin = itkVectorImagePointer->GetOrigin();
         parameters.m_SignalGen.m_ImageDirection = itkVectorImagePointer->GetDirection();
         parameters.m_SignalGen.m_Bvalue = static_cast<mitk::FloatProperty*>(dwi->GetProperty(mitk::DiffusionPropertyHelper::REFERENCEBVALUEPROPERTYNAME.c_str()).GetPointer() )->GetValue();
         parameters.m_SignalGen.SetGradienDirections(static_cast<mitk::GradientDirectionsProperty*>( dwi->GetProperty(mitk::DiffusionPropertyHelper::GRADIENTCONTAINERPROPERTYNAME.c_str()).GetPointer() )->GetGradientDirectionsContainer());
     }
     else if (m_Controls->m_TemplateComboBox->GetSelectedNode().IsNotNull())   // use geometry of selected image
     {
         mitk::Image::Pointer img = dynamic_cast<mitk::Image*>(m_Controls->m_TemplateComboBox->GetSelectedNode()->GetData());
         itk::Image< float, 3 >::Pointer itkImg = itk::Image< float, 3 >::New();
         CastToItkImage< itk::Image< float, 3 > >(img, itkImg);
 
         parameters.m_SignalGen.m_ImageRegion = itkImg->GetLargestPossibleRegion();
         parameters.m_SignalGen.m_ImageSpacing = itkImg->GetSpacing();
         parameters.m_SignalGen.m_ImageOrigin = itkImg->GetOrigin();
         parameters.m_SignalGen.m_ImageDirection = itkImg->GetDirection();
         parameters.m_SignalGen.SetNumWeightedVolumes(m_Controls->m_NumGradientsBox->value());
         parameters.m_SignalGen.m_Bvalue = m_Controls->m_BvalueBox->value();
     }
     else    // use GUI parameters
     {
         parameters.m_SignalGen.m_ImageRegion.SetSize(0, m_Controls->m_SizeX->value());
         parameters.m_SignalGen.m_ImageRegion.SetSize(1, m_Controls->m_SizeY->value());
         parameters.m_SignalGen.m_ImageRegion.SetSize(2, m_Controls->m_SizeZ->value());
         parameters.m_SignalGen.m_ImageSpacing[0] = m_Controls->m_SpacingX->value();
         parameters.m_SignalGen.m_ImageSpacing[1] = m_Controls->m_SpacingY->value();
         parameters.m_SignalGen.m_ImageSpacing[2] = m_Controls->m_SpacingZ->value();
         parameters.m_SignalGen.m_ImageOrigin[0] = parameters.m_SignalGen.m_ImageSpacing[0]/2;
         parameters.m_SignalGen.m_ImageOrigin[1] = parameters.m_SignalGen.m_ImageSpacing[1]/2;
         parameters.m_SignalGen.m_ImageOrigin[2] = parameters.m_SignalGen.m_ImageSpacing[2]/2;
         parameters.m_SignalGen.m_ImageDirection.SetIdentity();
         parameters.m_SignalGen.SetNumWeightedVolumes(m_Controls->m_NumGradientsBox->value());
         parameters.m_SignalGen.m_Bvalue = m_Controls->m_BvalueBox->value();
         parameters.m_SignalGen.GenerateGradientHalfShell();
     }
 
     // signal relaxation
     parameters.m_SignalGen.m_DoSimulateRelaxation = m_Controls->m_RelaxationBox->isChecked();
     parameters.m_SignalGen.m_SimulateKspaceAcquisition = parameters.m_SignalGen.m_DoSimulateRelaxation;
     if (parameters.m_SignalGen.m_DoSimulateRelaxation && m_Controls->m_FiberBundleComboBox->GetSelectedNode().IsNotNull() )
         parameters.m_Misc.m_ArtifactModelString += "_RELAX";
 
     // N/2 ghosts
     parameters.m_Misc.m_CheckAddGhostsBox = m_Controls->m_AddGhosts->isChecked();
     if (m_Controls->m_AddGhosts->isChecked())
     {
         parameters.m_SignalGen.m_SimulateKspaceAcquisition = true;
         parameters.m_Misc.m_ArtifactModelString += "_GHOST";
         parameters.m_SignalGen.m_KspaceLineOffset = m_Controls->m_kOffsetBox->value();
         parameters.m_Misc.m_ResultNode->AddProperty("Fiberfox.Ghost", DoubleProperty::New(parameters.m_SignalGen.m_KspaceLineOffset));
     }
     else
         parameters.m_SignalGen.m_KspaceLineOffset = 0;
 
     // Aliasing
     parameters.m_Misc.m_CheckAddAliasingBox = m_Controls->m_AddAliasing->isChecked();
     if (m_Controls->m_AddAliasing->isChecked())
     {
         parameters.m_SignalGen.m_SimulateKspaceAcquisition = true;
         parameters.m_Misc.m_ArtifactModelString += "_ALIASING";
         parameters.m_SignalGen.m_CroppingFactor = (100-m_Controls->m_WrapBox->value())/100;
         parameters.m_Misc.m_ResultNode->AddProperty("Fiberfox.Aliasing", DoubleProperty::New(m_Controls->m_WrapBox->value()));
     }
 
     // Spikes
     parameters.m_Misc.m_CheckAddSpikesBox = m_Controls->m_AddSpikes->isChecked();
     if (m_Controls->m_AddSpikes->isChecked())
     {
         parameters.m_SignalGen.m_SimulateKspaceAcquisition = true;
         parameters.m_SignalGen.m_Spikes = m_Controls->m_SpikeNumBox->value();
         parameters.m_SignalGen.m_SpikeAmplitude = m_Controls->m_SpikeScaleBox->value();
         parameters.m_Misc.m_ArtifactModelString += "_SPIKES";
         parameters.m_Misc.m_ResultNode->AddProperty("Fiberfox.Spikes.Number", IntProperty::New(parameters.m_SignalGen.m_Spikes));
         parameters.m_Misc.m_ResultNode->AddProperty("Fiberfox.Spikes.Amplitude", DoubleProperty::New(parameters.m_SignalGen.m_SpikeAmplitude));
     }
 
     // gibbs ringing
     parameters.m_SignalGen.m_DoAddGibbsRinging = m_Controls->m_AddGibbsRinging->isChecked();
     if (m_Controls->m_AddGibbsRinging->isChecked())
     {
         parameters.m_SignalGen.m_SimulateKspaceAcquisition = true;
         parameters.m_Misc.m_ResultNode->AddProperty("Fiberfox.Ringing", BoolProperty::New(true));
         parameters.m_Misc.m_ArtifactModelString += "_RINGING";
     }
 
     // add distortions
     parameters.m_Misc.m_CheckAddDistortionsBox = m_Controls->m_AddDistortions->isChecked();
     if (m_Controls->m_AddDistortions->isChecked() && m_Controls->m_FrequencyMapBox->GetSelectedNode().IsNotNull())
     {
         mitk::DataNode::Pointer fMapNode = m_Controls->m_FrequencyMapBox->GetSelectedNode();
         mitk::Image* img = dynamic_cast<mitk::Image*>(fMapNode->GetData());
         ItkDoubleImgType::Pointer itkImg = ItkDoubleImgType::New();
         CastToItkImage< ItkDoubleImgType >(img, itkImg);
 
         if (m_Controls->m_TemplateComboBox->GetSelectedNode().IsNull())   // use geometry of frequency map
         {
             parameters.m_SignalGen.m_ImageRegion = itkImg->GetLargestPossibleRegion();
             parameters.m_SignalGen.m_ImageSpacing = itkImg->GetSpacing();
             parameters.m_SignalGen.m_ImageOrigin = itkImg->GetOrigin();
             parameters.m_SignalGen.m_ImageDirection = itkImg->GetDirection();
         }
 
         if (parameters.m_SignalGen.m_ImageRegion.GetSize(0)==itkImg->GetLargestPossibleRegion().GetSize(0) &&
                 parameters.m_SignalGen.m_ImageRegion.GetSize(1)==itkImg->GetLargestPossibleRegion().GetSize(1) &&
                 parameters.m_SignalGen.m_ImageRegion.GetSize(2)==itkImg->GetLargestPossibleRegion().GetSize(2))
         {
             parameters.m_SignalGen.m_SimulateKspaceAcquisition = true;
             itk::ImageDuplicator<ItkDoubleImgType>::Pointer duplicator = itk::ImageDuplicator<ItkDoubleImgType>::New();
             duplicator->SetInputImage(itkImg);
             duplicator->Update();
             parameters.m_SignalGen.m_FrequencyMap = duplicator->GetOutput();
             parameters.m_Misc.m_ArtifactModelString += "_DISTORTED";
             parameters.m_Misc.m_ResultNode->AddProperty("Fiberfox.Distortions", BoolProperty::New(true));
         }
     }
 
     parameters.m_SignalGen.m_EddyStrength = 0;
     parameters.m_Misc.m_CheckAddEddyCurrentsBox = m_Controls->m_AddEddy->isChecked();
     if (m_Controls->m_AddEddy->isChecked())
     {
         parameters.m_SignalGen.m_EddyStrength = m_Controls->m_EddyGradientStrength->value();
         parameters.m_Misc.m_ArtifactModelString += "_EDDY";
         parameters.m_Misc.m_ResultNode->AddProperty("Fiberfox.Eddy-strength", DoubleProperty::New(parameters.m_SignalGen.m_EddyStrength));
     }
 
     // Motion
     parameters.m_SignalGen.m_DoAddMotion = m_Controls->m_AddMotion->isChecked();
     parameters.m_SignalGen.m_DoRandomizeMotion = m_Controls->m_RandomMotion->isChecked();
     parameters.m_SignalGen.m_Translation[0] = m_Controls->m_MaxTranslationBoxX->value();
     parameters.m_SignalGen.m_Translation[1] = m_Controls->m_MaxTranslationBoxY->value();
     parameters.m_SignalGen.m_Translation[2] = m_Controls->m_MaxTranslationBoxZ->value();
     parameters.m_SignalGen.m_Rotation[0] = m_Controls->m_MaxRotationBoxX->value();
     parameters.m_SignalGen.m_Rotation[1] = m_Controls->m_MaxRotationBoxY->value();
     parameters.m_SignalGen.m_Rotation[2] = m_Controls->m_MaxRotationBoxZ->value();
     if ( m_Controls->m_AddMotion->isChecked() && m_Controls->m_FiberBundleComboBox->GetSelectedNode().IsNotNull() )
     {
         parameters.m_Misc.m_ArtifactModelString += "_MOTION";
         parameters.m_Misc.m_ResultNode->AddProperty("Fiberfox.Motion.Random", BoolProperty::New(parameters.m_SignalGen.m_DoRandomizeMotion));
         parameters.m_Misc.m_ResultNode->AddProperty("Fiberfox.Motion.Translation-x", DoubleProperty::New(parameters.m_SignalGen.m_Translation[0]));
         parameters.m_Misc.m_ResultNode->AddProperty("Fiberfox.Motion.Translation-y", DoubleProperty::New(parameters.m_SignalGen.m_Translation[1]));
         parameters.m_Misc.m_ResultNode->AddProperty("Fiberfox.Motion.Translation-z", DoubleProperty::New(parameters.m_SignalGen.m_Translation[2]));
         parameters.m_Misc.m_ResultNode->AddProperty("Fiberfox.Motion.Rotation-x", DoubleProperty::New(parameters.m_SignalGen.m_Rotation[0]));
         parameters.m_Misc.m_ResultNode->AddProperty("Fiberfox.Motion.Rotation-y", DoubleProperty::New(parameters.m_SignalGen.m_Rotation[1]));
         parameters.m_Misc.m_ResultNode->AddProperty("Fiberfox.Motion.Rotation-z", DoubleProperty::New(parameters.m_SignalGen.m_Rotation[2]));
     }
 
     // other imaging parameters
     parameters.m_SignalGen.m_tLine = m_Controls->m_LineReadoutTimeBox->value();
     parameters.m_SignalGen.m_tInhom = m_Controls->m_T2starBox->value();
     parameters.m_SignalGen.m_tEcho = m_Controls->m_TEbox->value();
     parameters.m_SignalGen.m_DoDisablePartialVolume = m_Controls->m_EnforcePureFiberVoxelsBox->isChecked();
     parameters.m_SignalGen.m_AxonRadius = m_Controls->m_FiberRadius->value();
     parameters.m_SignalGen.m_SignalScale = m_Controls->m_SignalScaleBox->value();
 
     // adjust echo time if needed
     if ( parameters.m_SignalGen.m_tEcho < parameters.m_SignalGen.m_ImageRegion.GetSize(1)*parameters.m_SignalGen.m_tLine )
     {
         this->m_Controls->m_TEbox->setValue( parameters.m_SignalGen.m_ImageRegion.GetSize(1)*parameters.m_SignalGen.m_tLine );
         parameters.m_SignalGen.m_tEcho = m_Controls->m_TEbox->value();
         QMessageBox::information( NULL, "Warning", "Echo time is too short! Time not sufficient to read slice. Automaticall adjusted to "+QString::number(parameters.m_SignalGen.m_tEcho)+" ms");
     }
 
     // Noise
     parameters.m_Misc.m_CheckAddNoiseBox = m_Controls->m_AddNoise->isChecked();
     if (m_Controls->m_AddNoise->isChecked())
     {
         double noiseVariance = m_Controls->m_NoiseLevel->value();
         {
             switch (m_Controls->m_NoiseDistributionBox->currentIndex())
             {
             case 0:
             {
                 parameters.m_NoiseModel = new mitk::RicianNoiseModel<ScalarType>();
                 parameters.m_Misc.m_ArtifactModelString += "_RICIAN-";
                 parameters.m_Misc.m_ResultNode->AddProperty("Fiberfox.Noise-Distribution", StringProperty::New("Rician"));
                 break;
             }
             case 1:
             {
                 parameters.m_NoiseModel = new mitk::ChiSquareNoiseModel<ScalarType>();
                 parameters.m_Misc.m_ArtifactModelString += "_CHISQUARED-";
                 parameters.m_Misc.m_ResultNode->AddProperty("Fiberfox.Noise-Distribution", StringProperty::New("Chi-squared"));
                 break;
             }
             default:
             {
                 parameters.m_NoiseModel = new mitk::RicianNoiseModel<ScalarType>();
                 parameters.m_Misc.m_ArtifactModelString += "_RICIAN-";
                 parameters.m_Misc.m_ResultNode->AddProperty("Fiberfox.Noise-Distribution", StringProperty::New("Rician"));
             }
             }
         }
         parameters.m_NoiseModel->SetNoiseVariance(noiseVariance);
         parameters.m_Misc.m_ArtifactModelString += QString::number(noiseVariance).toStdString();
         parameters.m_Misc.m_ResultNode->AddProperty("Fiberfox.Noise-Variance", DoubleProperty::New(noiseVariance));
     }
 
     // adjusting line readout time to the adapted image size needed for the DFT
     unsigned int y = parameters.m_SignalGen.m_ImageRegion.GetSize(1);
     y += y%2;
     if ( y>parameters.m_SignalGen.m_ImageRegion.GetSize(1) )
         parameters.m_SignalGen.m_tLine *= (double)parameters.m_SignalGen.m_ImageRegion.GetSize(1)/y;
 
     // signal models
     {
         // compartment 1
         switch (m_Controls->m_Compartment1Box->currentIndex())
         {
         case 0:
         {
             mitk::StickModel<ScalarType>* model = new mitk::StickModel<ScalarType>();
             model->SetGradientList(parameters.m_SignalGen.GetGradientDirections());
             model->SetBvalue(parameters.m_SignalGen.m_Bvalue);
             model->SetDiffusivity(m_Controls->m_StickWidget1->GetD());
             model->SetT2(m_Controls->m_StickWidget1->GetT2());
             model->m_CompartmentId = 1;
             parameters.m_FiberModelList.push_back(model);
             parameters.m_Misc.m_SignalModelString += "Stick";
             parameters.m_Misc.m_ResultNode->AddProperty("Fiberfox.Compartment1.Description", StringProperty::New("Intra-axonal compartment") );
             parameters.m_Misc.m_ResultNode->AddProperty("Fiberfox.Compartment1.Model", StringProperty::New("Stick") );
             parameters.m_Misc.m_ResultNode->AddProperty("Fiberfox.Compartment1.D", DoubleProperty::New(m_Controls->m_StickWidget1->GetD()) );
             parameters.m_Misc.m_ResultNode->AddProperty("Fiberfox.Compartment1.T2", DoubleProperty::New(model->GetT2()) );
             break;
         }
         case 1:
         {
             mitk::TensorModel<ScalarType>* model = new mitk::TensorModel<ScalarType>();
             model->SetGradientList(parameters.m_SignalGen.GetGradientDirections());
             model->SetBvalue(parameters.m_SignalGen.m_Bvalue);
             model->SetDiffusivity1(m_Controls->m_ZeppelinWidget1->GetD1());
             model->SetDiffusivity2(m_Controls->m_ZeppelinWidget1->GetD2());
             model->SetDiffusivity3(m_Controls->m_ZeppelinWidget1->GetD2());
             model->SetT2(m_Controls->m_ZeppelinWidget1->GetT2());
             model->m_CompartmentId = 1;
             parameters.m_FiberModelList.push_back(model);
             parameters.m_Misc.m_SignalModelString += "Zeppelin";
             parameters.m_Misc.m_ResultNode->AddProperty("Fiberfox.Compartment1.Description", StringProperty::New("Intra-axonal compartment") );
             parameters.m_Misc.m_ResultNode->AddProperty("Fiberfox.Compartment1.Model", StringProperty::New("Zeppelin") );
             parameters.m_Misc.m_ResultNode->AddProperty("Fiberfox.Compartment1.D1", DoubleProperty::New(m_Controls->m_ZeppelinWidget1->GetD1()) );
             parameters.m_Misc.m_ResultNode->AddProperty("Fiberfox.Compartment1.D2", DoubleProperty::New(m_Controls->m_ZeppelinWidget1->GetD2()) );
             parameters.m_Misc.m_ResultNode->AddProperty("Fiberfox.Compartment1.T2", DoubleProperty::New(model->GetT2()) );
             break;
         }
         case 2:
         {
             mitk::TensorModel<ScalarType>* model = new mitk::TensorModel<ScalarType>();
             model->SetGradientList(parameters.m_SignalGen.GetGradientDirections());
             model->SetBvalue(parameters.m_SignalGen.m_Bvalue);
             model->SetDiffusivity1(m_Controls->m_TensorWidget1->GetD1());
             model->SetDiffusivity2(m_Controls->m_TensorWidget1->GetD2());
             model->SetDiffusivity3(m_Controls->m_TensorWidget1->GetD3());
             model->SetT2(m_Controls->m_TensorWidget1->GetT2());
             model->m_CompartmentId = 1;
             parameters.m_FiberModelList.push_back(model);
             parameters.m_Misc.m_SignalModelString += "Tensor";
             parameters.m_Misc.m_ResultNode->AddProperty("Fiberfox.Compartment1.Description", StringProperty::New("Intra-axonal compartment") );
             parameters.m_Misc.m_ResultNode->AddProperty("Fiberfox.Compartment1.Model", StringProperty::New("Tensor") );
             parameters.m_Misc.m_ResultNode->AddProperty("Fiberfox.Compartment1.D1", DoubleProperty::New(m_Controls->m_TensorWidget1->GetD1()) );
             parameters.m_Misc.m_ResultNode->AddProperty("Fiberfox.Compartment1.D2", DoubleProperty::New(m_Controls->m_TensorWidget1->GetD2()) );
             parameters.m_Misc.m_ResultNode->AddProperty("Fiberfox.Compartment1.D3", DoubleProperty::New(m_Controls->m_TensorWidget1->GetD3()) );
             parameters.m_Misc.m_ResultNode->AddProperty("Fiberfox.Compartment1.T2", DoubleProperty::New(model->GetT2()) );
             break;
         }
         case 3:
         {
             mitk::RawShModel<ScalarType>* model = new mitk::RawShModel<ScalarType>();
             parameters.m_SignalGen.m_DoSimulateRelaxation = false;
             model->SetGradientList(parameters.m_SignalGen.GetGradientDirections());
             model->SetMaxNumKernels(m_Controls->m_PrototypeWidget1->GetNumberOfSamples());
             model->SetFaRange(m_Controls->m_PrototypeWidget1->GetMinFa(), m_Controls->m_PrototypeWidget1->GetMaxFa());
             model->SetAdcRange(m_Controls->m_PrototypeWidget1->GetMinAdc(), m_Controls->m_PrototypeWidget1->GetMaxAdc());
             model->m_CompartmentId = 1;
             parameters.m_FiberModelList.push_back(model);
             parameters.m_Misc.m_SignalModelString += "Prototype";
             parameters.m_Misc.m_ResultNode->AddProperty("Fiberfox.Compartment1.Description", StringProperty::New("Intra-axonal compartment") );
             parameters.m_Misc.m_ResultNode->AddProperty("Fiberfox.Compartment1.Model", StringProperty::New("Prototype") );
             break;
         }
         }
 
         // compartment 2
         switch (m_Controls->m_Compartment2Box->currentIndex())
         {
         case 0:
             break;
         case 1:
         {
             mitk::StickModel<ScalarType>* model = new mitk::StickModel<ScalarType>();
             model->SetGradientList(parameters.m_SignalGen.GetGradientDirections());
             model->SetBvalue(parameters.m_SignalGen.m_Bvalue);
             model->SetDiffusivity(m_Controls->m_StickWidget2->GetD());
             model->SetT2(m_Controls->m_StickWidget2->GetT2());
             model->m_CompartmentId = 2;
             parameters.m_FiberModelList.push_back(model);
             parameters.m_Misc.m_SignalModelString += "Stick";
             parameters.m_Misc.m_ResultNode->AddProperty("Fiberfox.Compartment2.Description", StringProperty::New("Inter-axonal compartment") );
             parameters.m_Misc.m_ResultNode->AddProperty("Fiberfox.Compartment2.Model", StringProperty::New("Stick") );
             parameters.m_Misc.m_ResultNode->AddProperty("Fiberfox.Compartment2.D", DoubleProperty::New(m_Controls->m_StickWidget2->GetD()) );
             parameters.m_Misc.m_ResultNode->AddProperty("Fiberfox.Compartment2.T2", DoubleProperty::New(model->GetT2()) );
             break;
         }
         case 2:
         {
             mitk::TensorModel<ScalarType>* model = new mitk::TensorModel<ScalarType>();
             model->SetGradientList(parameters.m_SignalGen.GetGradientDirections());
             model->SetBvalue(parameters.m_SignalGen.m_Bvalue);
             model->SetDiffusivity1(m_Controls->m_ZeppelinWidget2->GetD1());
             model->SetDiffusivity2(m_Controls->m_ZeppelinWidget2->GetD2());
             model->SetDiffusivity3(m_Controls->m_ZeppelinWidget2->GetD2());
             model->SetT2(m_Controls->m_ZeppelinWidget2->GetT2());
             model->m_CompartmentId = 2;
             parameters.m_FiberModelList.push_back(model);
             parameters.m_Misc.m_SignalModelString += "Zeppelin";
             parameters.m_Misc.m_ResultNode->AddProperty("Fiberfox.Compartment2.Description", StringProperty::New("Inter-axonal compartment") );
             parameters.m_Misc.m_ResultNode->AddProperty("Fiberfox.Compartment2.Model", StringProperty::New("Zeppelin") );
             parameters.m_Misc.m_ResultNode->AddProperty("Fiberfox.Compartment2.D1", DoubleProperty::New(m_Controls->m_ZeppelinWidget2->GetD1()) );
             parameters.m_Misc.m_ResultNode->AddProperty("Fiberfox.Compartment2.D2", DoubleProperty::New(m_Controls->m_ZeppelinWidget2->GetD2()) );
             parameters.m_Misc.m_ResultNode->AddProperty("Fiberfox.Compartment2.T2", DoubleProperty::New(model->GetT2()) );
             break;
         }
         case 3:
         {
             mitk::TensorModel<ScalarType>* model = new mitk::TensorModel<ScalarType>();
             model->SetGradientList(parameters.m_SignalGen.GetGradientDirections());
             model->SetBvalue(parameters.m_SignalGen.m_Bvalue);
             model->SetDiffusivity1(m_Controls->m_TensorWidget2->GetD1());
             model->SetDiffusivity2(m_Controls->m_TensorWidget2->GetD2());
             model->SetDiffusivity3(m_Controls->m_TensorWidget2->GetD3());
             model->SetT2(m_Controls->m_TensorWidget2->GetT2());
             model->m_CompartmentId = 2;
             parameters.m_FiberModelList.push_back(model);
             parameters.m_Misc.m_SignalModelString += "Tensor";
             parameters.m_Misc.m_ResultNode->AddProperty("Fiberfox.Compartment2.Description", StringProperty::New("Inter-axonal compartment") );
             parameters.m_Misc.m_ResultNode->AddProperty("Fiberfox.Compartment2.Model", StringProperty::New("Tensor") );
             parameters.m_Misc.m_ResultNode->AddProperty("Fiberfox.Compartment2.D1", DoubleProperty::New(m_Controls->m_TensorWidget2->GetD1()) );
             parameters.m_Misc.m_ResultNode->AddProperty("Fiberfox.Compartment2.D2", DoubleProperty::New(m_Controls->m_TensorWidget2->GetD2()) );
             parameters.m_Misc.m_ResultNode->AddProperty("Fiberfox.Compartment2.D3", DoubleProperty::New(m_Controls->m_TensorWidget2->GetD3()) );
             parameters.m_Misc.m_ResultNode->AddProperty("Fiberfox.Compartment2.T2", DoubleProperty::New(model->GetT2()) );
             break;
         }
         }
 
         // compartment 3
         switch (m_Controls->m_Compartment3Box->currentIndex())
         {
         case 0:
         {
             mitk::BallModel<ScalarType>* model = new mitk::BallModel<ScalarType>();
             model->SetGradientList(parameters.m_SignalGen.GetGradientDirections());
             model->SetBvalue(parameters.m_SignalGen.m_Bvalue);
             model->SetDiffusivity(m_Controls->m_BallWidget1->GetD());
             model->SetT2(m_Controls->m_BallWidget1->GetT2());
             model->m_CompartmentId = 3;
             parameters.m_NonFiberModelList.push_back(model);
             parameters.m_Misc.m_SignalModelString += "Ball";
             parameters.m_Misc.m_ResultNode->AddProperty("Fiberfox.Compartment3.Description", StringProperty::New("Extra-axonal compartment 1") );
             parameters.m_Misc.m_ResultNode->AddProperty("Fiberfox.Compartment3.Model", StringProperty::New("Ball") );
             parameters.m_Misc.m_ResultNode->AddProperty("Fiberfox.Compartment3.D", DoubleProperty::New(m_Controls->m_BallWidget1->GetD()) );
             parameters.m_Misc.m_ResultNode->AddProperty("Fiberfox.Compartment3.T2", DoubleProperty::New(model->GetT2()) );
             break;
         }
         case 1:
         {
             mitk::AstroStickModel<ScalarType>* model = new mitk::AstroStickModel<ScalarType>();
             model->SetGradientList(parameters.m_SignalGen.GetGradientDirections());
             model->SetBvalue(parameters.m_SignalGen.m_Bvalue);
             model->SetDiffusivity(m_Controls->m_AstrosticksWidget1->GetD());
             model->SetT2(m_Controls->m_AstrosticksWidget1->GetT2());
             model->SetRandomizeSticks(m_Controls->m_AstrosticksWidget1->GetRandomizeSticks());
             model->m_CompartmentId = 3;
             parameters.m_NonFiberModelList.push_back(model);
             parameters.m_Misc.m_SignalModelString += "Astrosticks";
             parameters.m_Misc.m_ResultNode->AddProperty("Fiberfox.Compartment3.Description", StringProperty::New("Extra-axonal compartment 1") );
             parameters.m_Misc.m_ResultNode->AddProperty("Fiberfox.Compartment3.Model", StringProperty::New("Astrosticks") );
             parameters.m_Misc.m_ResultNode->AddProperty("Fiberfox.Compartment3.D", DoubleProperty::New(m_Controls->m_AstrosticksWidget1->GetD()) );
             parameters.m_Misc.m_ResultNode->AddProperty("Fiberfox.Compartment3.T2", DoubleProperty::New(model->GetT2()) );
             parameters.m_Misc.m_ResultNode->AddProperty("Fiberfox.Compartment3.RandomSticks", BoolProperty::New(m_Controls->m_AstrosticksWidget1->GetRandomizeSticks()) );
             break;
         }
         case 2:
         {
             mitk::DotModel<ScalarType>* model = new mitk::DotModel<ScalarType>();
             model->SetGradientList(parameters.m_SignalGen.GetGradientDirections());
             model->SetT2(m_Controls->m_DotWidget1->GetT2());
             model->m_CompartmentId = 3;
             parameters.m_NonFiberModelList.push_back(model);
             parameters.m_Misc.m_SignalModelString += "Dot";
             parameters.m_Misc.m_ResultNode->AddProperty("Fiberfox.Compartment3.Description", StringProperty::New("Extra-axonal compartment 1") );
             parameters.m_Misc.m_ResultNode->AddProperty("Fiberfox.Compartment3.Model", StringProperty::New("Dot") );
             parameters.m_Misc.m_ResultNode->AddProperty("Fiberfox.Compartment3.T2", DoubleProperty::New(model->GetT2()) );
             break;
         }
         case 3:
         {
             mitk::RawShModel<ScalarType>* model = new mitk::RawShModel<ScalarType>();
             parameters.m_SignalGen.m_DoSimulateRelaxation = false;
             model->SetGradientList(parameters.m_SignalGen.GetGradientDirections());
             model->SetMaxNumKernels(m_Controls->m_PrototypeWidget3->GetNumberOfSamples());
             model->SetFaRange(m_Controls->m_PrototypeWidget3->GetMinFa(), m_Controls->m_PrototypeWidget3->GetMaxFa());
             model->SetAdcRange(m_Controls->m_PrototypeWidget3->GetMinAdc(), m_Controls->m_PrototypeWidget3->GetMaxAdc());
             model->m_CompartmentId = 3;
             parameters.m_NonFiberModelList.push_back(model);
             parameters.m_Misc.m_SignalModelString += "Prototype";
             parameters.m_Misc.m_ResultNode->AddProperty("Fiberfox.Compartment3.Description", StringProperty::New("Extra-axonal compartment 1") );
             parameters.m_Misc.m_ResultNode->AddProperty("Fiberfox.Compartment3.Model", StringProperty::New("Prototype") );
             break;
         }
         }
 
         // compartment 4
         ItkDoubleImgType::Pointer comp4VolumeImage = NULL;
         ItkDoubleImgType::Pointer comp3VolumeImage = NULL;
         if (m_Controls->m_Compartment4Box->currentIndex()>0)
         {
             mitk::DataNode::Pointer volumeNode = m_Controls->m_Comp4VolumeFraction->GetSelectedNode();
             if (volumeNode.IsNull())
             {
                 QMessageBox::information( NULL, "Information", "No volume fraction image selected! Second extra-axonal compartment has been disabled for this simultation.");
                 MITK_WARN << "No volume fraction image selected! Second extra-axonal compartment has been disabled.";
             }
             else
             {
                 MITK_INFO << "Rescaling volume fraction image...";
                 comp4VolumeImage = ItkDoubleImgType::New();
                 mitk::Image* img = dynamic_cast<mitk::Image*>(volumeNode->GetData());
                 CastToItkImage< ItkDoubleImgType >(img, comp4VolumeImage);
 
                 double max = itk::NumericTraits<double>::min();
                 double min = itk::NumericTraits<double>::max();
 
                 itk::ImageRegionIterator< ItkDoubleImgType > it(comp4VolumeImage, comp4VolumeImage->GetLargestPossibleRegion());
                 while(!it.IsAtEnd())
                 {
                     if (parameters.m_SignalGen.m_MaskImage.IsNotNull() && parameters.m_SignalGen.m_MaskImage->GetPixel(it.GetIndex())<=0)
                     {
                         it.Set(0.0);
                         ++it;
                         continue;
                     }
                     if (it.Get()>900)
                         it.Set(900);
 
                     if (it.Get()>max)
                         max = it.Get();
                     if (it.Get()<min)
                         min = it.Get();
                     ++it;
                 }
                 itk::ShiftScaleImageFilter< ItkDoubleImgType, ItkDoubleImgType >::Pointer scaler = itk::ShiftScaleImageFilter< ItkDoubleImgType, ItkDoubleImgType >::New();
                 scaler->SetInput(comp4VolumeImage);
                 scaler->SetShift(-min);
                 scaler->SetScale(1.0/(max-min));
                 scaler->Update();
                 comp4VolumeImage = scaler->GetOutput();
 
 //                itk::ImageFileWriter< ItkDoubleImgType >::Pointer wr = itk::ImageFileWriter< ItkDoubleImgType >::New();
 //                wr->SetInput(comp4VolumeImage);
 //                wr->SetFileName("/local/comp4.nrrd");
 //                wr->Update();
 
                 //            if (max>1 || min<0) // are volume fractions between 0 and 1?
                 //            {
                 //                itk::RescaleIntensityImageFilter<ItkDoubleImgType,ItkDoubleImgType>::Pointer rescaler = itk::RescaleIntensityImageFilter<ItkDoubleImgType,ItkDoubleImgType>::New();
                 //                rescaler->SetInput(0, comp4VolumeImage);
                 //                rescaler->SetOutputMaximum(1);
                 //                rescaler->SetOutputMinimum(0);
                 //                rescaler->Update();
                 //                comp4VolumeImage = rescaler->GetOutput();
                 //            }
 
                 itk::InvertIntensityImageFilter< ItkDoubleImgType, ItkDoubleImgType >::Pointer inverter = itk::InvertIntensityImageFilter< ItkDoubleImgType, ItkDoubleImgType >::New();
                 inverter->SetMaximum(1.0);
                 inverter->SetInput(comp4VolumeImage);
                 inverter->Update();
                 comp3VolumeImage = inverter->GetOutput();
             }
         }
 
         if (comp4VolumeImage.IsNotNull())
         {
             switch (m_Controls->m_Compartment4Box->currentIndex())
             {
             case 0:
                 break;
             case 1:
             {
                 mitk::BallModel<ScalarType>* model = new mitk::BallModel<ScalarType>();
                 model->SetGradientList(parameters.m_SignalGen.GetGradientDirections());
                 model->SetBvalue(parameters.m_SignalGen.m_Bvalue);
                 model->SetDiffusivity(m_Controls->m_BallWidget2->GetD());
                 model->SetT2(m_Controls->m_BallWidget2->GetT2());
                 model->SetVolumeFractionImage(comp4VolumeImage);
                 model->m_CompartmentId = 4;
                 parameters.m_NonFiberModelList.back()->SetVolumeFractionImage(comp3VolumeImage);
                 parameters.m_NonFiberModelList.push_back(model);
                 parameters.m_Misc.m_SignalModelString += "Ball";
                 parameters.m_Misc.m_ResultNode->AddProperty("Fiberfox.Compartment4.Description", StringProperty::New("Extra-axonal compartment 2") );
                 parameters.m_Misc.m_ResultNode->AddProperty("Fiberfox.Compartment4.Model", StringProperty::New("Ball") );
                 parameters.m_Misc.m_ResultNode->AddProperty("Fiberfox.Compartment4.D", DoubleProperty::New(m_Controls->m_BallWidget2->GetD()) );
                 parameters.m_Misc.m_ResultNode->AddProperty("Fiberfox.Compartment4.T2", DoubleProperty::New(model->GetT2()) );
                 break;
             }
             case 2:
             {
                 mitk::AstroStickModel<ScalarType>* model = new mitk::AstroStickModel<ScalarType>();
                 model->SetGradientList(parameters.m_SignalGen.GetGradientDirections());
                 model->SetBvalue(parameters.m_SignalGen.m_Bvalue);
                 model->SetDiffusivity(m_Controls->m_AstrosticksWidget2->GetD());
                 model->SetT2(m_Controls->m_AstrosticksWidget2->GetT2());
                 model->SetRandomizeSticks(m_Controls->m_AstrosticksWidget2->GetRandomizeSticks());
                 parameters.m_NonFiberModelList.back()->SetVolumeFractionImage(comp3VolumeImage);
                 model->SetVolumeFractionImage(comp4VolumeImage);
                 model->m_CompartmentId = 4;
                 parameters.m_NonFiberModelList.push_back(model);
                 parameters.m_Misc.m_SignalModelString += "Astrosticks";
                 parameters.m_Misc.m_ResultNode->AddProperty("Fiberfox.Compartment4.Description", StringProperty::New("Extra-axonal compartment 2") );
                 parameters.m_Misc.m_ResultNode->AddProperty("Fiberfox.Compartment4.Model", StringProperty::New("Astrosticks") );
                 parameters.m_Misc.m_ResultNode->AddProperty("Fiberfox.Compartment4.D", DoubleProperty::New(m_Controls->m_AstrosticksWidget2->GetD()) );
                 parameters.m_Misc.m_ResultNode->AddProperty("Fiberfox.Compartment4.T2", DoubleProperty::New(model->GetT2()) );
                 parameters.m_Misc.m_ResultNode->AddProperty("Fiberfox.Compartment4.RandomSticks", BoolProperty::New(m_Controls->m_AstrosticksWidget2->GetRandomizeSticks()) );
                 break;
             }
             case 3:
             {
                 mitk::DotModel<ScalarType>* model = new mitk::DotModel<ScalarType>();
                 model->SetGradientList(parameters.m_SignalGen.GetGradientDirections());
                 model->SetT2(m_Controls->m_DotWidget2->GetT2());
                 model->SetVolumeFractionImage(comp4VolumeImage);
                 model->m_CompartmentId = 4;
                 parameters.m_NonFiberModelList.back()->SetVolumeFractionImage(comp3VolumeImage);
                 parameters.m_NonFiberModelList.push_back(model);
                 parameters.m_Misc.m_SignalModelString += "Dot";
                 parameters.m_Misc.m_ResultNode->AddProperty("Fiberfox.Compartment4.Description", StringProperty::New("Extra-axonal compartment 2") );
                 parameters.m_Misc.m_ResultNode->AddProperty("Fiberfox.Compartment4.Model", StringProperty::New("Dot") );
                 parameters.m_Misc.m_ResultNode->AddProperty("Fiberfox.Compartment4.T2", DoubleProperty::New(model->GetT2()) );
                 break;
             }
             case 4:
             {
                 mitk::RawShModel<ScalarType>* model = new mitk::RawShModel<ScalarType>();
                 parameters.m_SignalGen.m_DoSimulateRelaxation = false;
                 model->SetGradientList(parameters.m_SignalGen.GetGradientDirections());
                 model->SetMaxNumKernels(m_Controls->m_PrototypeWidget4->GetNumberOfSamples());
                 model->SetFaRange(m_Controls->m_PrototypeWidget4->GetMinFa(), m_Controls->m_PrototypeWidget4->GetMaxFa());
                 model->SetAdcRange(m_Controls->m_PrototypeWidget4->GetMinAdc(), m_Controls->m_PrototypeWidget4->GetMaxAdc());
                 model->SetVolumeFractionImage(comp4VolumeImage);
                 model->m_CompartmentId = 4;
                 parameters.m_NonFiberModelList.back()->SetVolumeFractionImage(comp3VolumeImage);
                 parameters.m_NonFiberModelList.push_back(model);
                 parameters.m_Misc.m_SignalModelString += "Prototype";
                 parameters.m_Misc.m_ResultNode->AddProperty("Fiberfox.Compartment4.Description", StringProperty::New("Extra-axonal compartment 2") );
                 parameters.m_Misc.m_ResultNode->AddProperty("Fiberfox.Compartment4.Model", StringProperty::New("Prototype") );
                 break;
             }
             }
         }
     }
 
     parameters.m_SignalGen.m_FiberSeparationThreshold = m_Controls->m_SeparationAngleBox->value();
     switch (m_Controls->m_DiffusionDirectionBox->currentIndex())
     {
     case 0:
         parameters.m_SignalGen.m_DiffusionDirectionMode = SignalGenerationParameters::FIBER_TANGENT_DIRECTIONS;
         break;
     case 1:
         parameters.m_SignalGen.m_DiffusionDirectionMode = SignalGenerationParameters::MAIN_FIBER_DIRECTIONS;
         break;
     case 2:
         parameters.m_SignalGen.m_DiffusionDirectionMode = SignalGenerationParameters::RANDOM_DIRECTIONS;
         parameters.m_SignalGen.m_DoAddMotion = false;
         parameters.m_SignalGen.m_DoAddGibbsRinging = false;
         parameters.m_SignalGen.m_KspaceLineOffset = 0.0;
         parameters.m_SignalGen.m_FrequencyMap = NULL;
         parameters.m_SignalGen.m_CroppingFactor = 1.0;
         parameters.m_SignalGen.m_EddyStrength = 0;
         break;
     default:
         parameters.m_SignalGen.m_DiffusionDirectionMode = SignalGenerationParameters::FIBER_TANGENT_DIRECTIONS;
     }
 
     parameters.m_Misc.m_ResultNode->AddProperty("Fiberfox.SignalScale", IntProperty::New(parameters.m_SignalGen.m_SignalScale));
     parameters.m_Misc.m_ResultNode->AddProperty("Fiberfox.FiberRadius", IntProperty::New(parameters.m_SignalGen.m_AxonRadius));
     parameters.m_Misc.m_ResultNode->AddProperty("Fiberfox.Tinhom", DoubleProperty::New(parameters.m_SignalGen.m_tInhom));
     parameters.m_Misc.m_ResultNode->AddProperty("Fiberfox.Tline", DoubleProperty::New(parameters.m_SignalGen.m_tLine));
     parameters.m_Misc.m_ResultNode->AddProperty("Fiberfox.TE", DoubleProperty::New(parameters.m_SignalGen.m_tEcho));
     parameters.m_Misc.m_ResultNode->AddProperty("Fiberfox.b-value", DoubleProperty::New(parameters.m_SignalGen.m_Bvalue));
     parameters.m_Misc.m_ResultNode->AddProperty("Fiberfox.NoPartialVolume", BoolProperty::New(parameters.m_SignalGen.m_DoDisablePartialVolume));
     parameters.m_Misc.m_ResultNode->AddProperty("Fiberfox.Relaxation", BoolProperty::New(parameters.m_SignalGen.m_DoSimulateRelaxation));
     parameters.m_Misc.m_ResultNode->AddProperty("binary", BoolProperty::New(false));
 
     parameters.m_Misc.m_CheckRealTimeFibersBox = m_Controls->m_RealTimeFibers->isChecked();
     parameters.m_Misc.m_CheckAdvancedFiberOptionsBox = m_Controls->m_AdvancedOptionsBox->isChecked();
     parameters.m_Misc.m_CheckIncludeFiducialsBox = m_Controls->m_IncludeFiducials->isChecked();
     parameters.m_Misc.m_CheckConstantRadiusBox = m_Controls->m_ConstantRadiusBox->isChecked();
 
     switch(m_Controls->m_DistributionBox->currentIndex())
     {
     case 0:
         parameters.m_FiberGen.m_Distribution = FiberGenerationParameters::DISTRIBUTE_UNIFORM;
         break;
     case 1:
         parameters.m_FiberGen.m_Distribution = FiberGenerationParameters::DISTRIBUTE_GAUSSIAN;
         break;
     default:
         parameters.m_FiberGen.m_Distribution = FiberGenerationParameters::DISTRIBUTE_UNIFORM;
     }
     parameters.m_FiberGen.m_Variance = m_Controls->m_VarianceBox->value();
     parameters.m_FiberGen.m_Density = m_Controls->m_FiberDensityBox->value();
     parameters.m_FiberGen.m_Sampling = m_Controls->m_FiberSamplingBox->value();
     parameters.m_FiberGen.m_Tension = m_Controls->m_TensionBox->value();
     parameters.m_FiberGen.m_Continuity = m_Controls->m_ContinuityBox->value();
     parameters.m_FiberGen.m_Bias = m_Controls->m_BiasBox->value();
     parameters.m_FiberGen.m_Rotation[0] = m_Controls->m_XrotBox->value();
     parameters.m_FiberGen.m_Rotation[1] = m_Controls->m_YrotBox->value();
     parameters.m_FiberGen.m_Rotation[2] = m_Controls->m_ZrotBox->value();
     parameters.m_FiberGen.m_Translation[0] = m_Controls->m_XtransBox->value();
     parameters.m_FiberGen.m_Translation[1] = m_Controls->m_YtransBox->value();
     parameters.m_FiberGen.m_Translation[2] = m_Controls->m_ZtransBox->value();
     parameters.m_FiberGen.m_Scale[0] = m_Controls->m_XscaleBox->value();
     parameters.m_FiberGen.m_Scale[1] = m_Controls->m_YscaleBox->value();
     parameters.m_FiberGen.m_Scale[2] = m_Controls->m_ZscaleBox->value();
 
     return parameters;
 }
 
 void QmitkFiberfoxView::SaveParameters()
 {
     FiberfoxParameters<> ffParamaters = UpdateImageParameters<double>();
 
     QString filename = QFileDialog::getSaveFileName(
                 0,
                 tr("Save Parameters"),
                 m_ParameterFile,
                 tr("Fiberfox Parameters (*.ffp)") );
 
     bool ok = true;
     bool first = true;
     bool dosampling = false;
     mitk::Image::Pointer diffImg = NULL;
     itk::Image< itk::DiffusionTensor3D< double >, 3 >::Pointer tensorImage = NULL;
     const int shOrder = 2;
     typedef itk::AnalyticalDiffusionQballReconstructionImageFilter<short,short,float,shOrder,QBALL_ODFSIZE> QballFilterType;
     QballFilterType::CoefficientImageType::Pointer itkFeatureImage = NULL;
     ItkDoubleImgType::Pointer adcImage = NULL;
 
     for (unsigned int i=0; i<ffParamaters.m_FiberModelList.size()+ffParamaters.m_NonFiberModelList.size(); i++)
     {
         mitk::RawShModel<>* model = NULL;
         if (i<ffParamaters.m_FiberModelList.size())
             model = dynamic_cast<  mitk::RawShModel<>* >(ffParamaters.m_FiberModelList.at(i));
         else
             model = dynamic_cast<  mitk::RawShModel<>* >(ffParamaters.m_NonFiberModelList.at(i-ffParamaters.m_FiberModelList.size()));
 
         if (model!=0 && model->GetNumberOfKernels()<=0)
         {
             if (first==true)
             {
                 if (QMessageBox::question(NULL, "Prototype signal sampling", "Do you want to sample prototype signals from the selected diffusion-weighted imag and save them?",QMessageBox::Yes,QMessageBox::No)==QMessageBox::Yes)
                     dosampling = true;
 
                 first = false;
                 if (dosampling && (m_Controls->m_TemplateComboBox->GetSelectedNode().IsNull() || !mitk::DiffusionPropertyHelper::IsDiffusionWeightedImage( dynamic_cast<mitk::Image*>(m_Controls->m_TemplateComboBox->GetSelectedNode()->GetData()))))
                 {
                     QMessageBox::information(NULL, "Parameter file not saved", "No diffusion-weighted image selected to sample signal from.");
                     return;
                 }
                 else if (dosampling)
                 {
                   diffImg = dynamic_cast<mitk::Image*>(m_Controls->m_TemplateComboBox->GetSelectedNode()->GetData());
 
                   typedef itk::DiffusionTensor3DReconstructionImageFilter< short, short, double > TensorReconstructionImageFilterType;
                   TensorReconstructionImageFilterType::Pointer filter = TensorReconstructionImageFilterType::New();
                   ItkDwiType::Pointer itkVectorImagePointer = ItkDwiType::New();
                   mitk::CastToItkImage(diffImg, itkVectorImagePointer);
                   filter->SetGradientImage( static_cast<mitk::GradientDirectionsProperty*>( diffImg->GetProperty(mitk::DiffusionPropertyHelper::GRADIENTCONTAINERPROPERTYNAME.c_str()).GetPointer() )->GetGradientDirectionsContainer(), itkVectorImagePointer );
                   filter->SetBValue( static_cast<mitk::FloatProperty*>(diffImg->GetProperty(mitk::DiffusionPropertyHelper::REFERENCEBVALUEPROPERTYNAME.c_str()).GetPointer() )->GetValue() );
 
                   filter->Update();
                   tensorImage = filter->GetOutput();
 
                   const int NumCoeffs = (shOrder*shOrder + shOrder + 2)/2 + shOrder;
                   QballFilterType::Pointer qballfilter = QballFilterType::New();
                   qballfilter->SetGradientImage( static_cast<mitk::GradientDirectionsProperty*>( diffImg->GetProperty(mitk::DiffusionPropertyHelper::GRADIENTCONTAINERPROPERTYNAME.c_str()).GetPointer() )->GetGradientDirectionsContainer(), itkVectorImagePointer );
                   qballfilter->SetBValue( static_cast<mitk::FloatProperty*>(diffImg->GetProperty(mitk::DiffusionPropertyHelper::REFERENCEBVALUEPROPERTYNAME.c_str()).GetPointer() )->GetValue() );
                   qballfilter->SetLambda(0.006);
                   qballfilter->SetNormalizationMethod(QballFilterType::QBAR_RAW_SIGNAL);
                   qballfilter->Update();
                   itkFeatureImage = qballfilter->GetCoefficientImage();
 
                   itk::AdcImageFilter< short, double >::Pointer adcFilter = itk::AdcImageFilter< short, double >::New();
                   adcFilter->SetInput( itkVectorImagePointer );
                   adcFilter->SetGradientDirections( static_cast<mitk::GradientDirectionsProperty*>( diffImg->GetProperty(mitk::DiffusionPropertyHelper::GRADIENTCONTAINERPROPERTYNAME.c_str()).GetPointer() )->GetGradientDirectionsContainer() );
                   adcFilter->SetB_value( static_cast<mitk::FloatProperty*>(diffImg->GetProperty(mitk::DiffusionPropertyHelper::REFERENCEBVALUEPROPERTYNAME.c_str()).GetPointer() )->GetValue() );
                   adcFilter->Update();
                   adcImage = adcFilter->GetOutput();
                 }
             }
 
             if (dosampling && diffImg.IsNotNull())
             {
                 ok = model->SampleKernels(diffImg, ffParamaters.m_SignalGen.m_MaskImage, tensorImage, itkFeatureImage, adcImage);
                 if (!ok)
                 {
                     QMessageBox::information( NULL, "Parameter file not saved", "No valid prototype signals could be sampled.");
                     return;
                 }
             }
         }
     }
 
     ffParamaters.SaveParameters(filename.toStdString());
     m_ParameterFile = filename;
 }
 
 void QmitkFiberfoxView::LoadParameters()
 {
     QString filename = QFileDialog::getOpenFileName(0, tr("Load Parameters"), QString(itksys::SystemTools::GetFilenamePath(m_ParameterFile.toStdString()).c_str()), tr("Fiberfox Parameters (*.ffp)") );
     if(filename.isEmpty() || filename.isNull())
         return;
 
     m_ParameterFile = filename;
 
     FiberfoxParameters<> parameters;
     parameters.LoadParameters(filename.toStdString());
 
     m_Controls->m_RealTimeFibers->setChecked(parameters.m_Misc.m_CheckRealTimeFibersBox);
     m_Controls->m_AdvancedOptionsBox->setChecked(parameters.m_Misc.m_CheckAdvancedFiberOptionsBox);
     m_Controls->m_IncludeFiducials->setChecked(parameters.m_Misc.m_CheckIncludeFiducialsBox);
     m_Controls->m_ConstantRadiusBox->setChecked(parameters.m_Misc.m_CheckConstantRadiusBox);
 
     m_Controls->m_DistributionBox->setCurrentIndex(parameters.m_FiberGen.m_Distribution);
     m_Controls->m_VarianceBox->setValue(parameters.m_FiberGen.m_Variance);
     m_Controls->m_FiberDensityBox->setValue(parameters.m_FiberGen.m_Density);
     m_Controls->m_FiberSamplingBox->setValue(parameters.m_FiberGen.m_Sampling);
     m_Controls->m_TensionBox->setValue(parameters.m_FiberGen.m_Tension);
     m_Controls->m_ContinuityBox->setValue(parameters.m_FiberGen.m_Continuity);
     m_Controls->m_BiasBox->setValue(parameters.m_FiberGen.m_Bias);
     m_Controls->m_XrotBox->setValue(parameters.m_FiberGen.m_Rotation[0]);
     m_Controls->m_YrotBox->setValue(parameters.m_FiberGen.m_Rotation[1]);
     m_Controls->m_ZrotBox->setValue(parameters.m_FiberGen.m_Rotation[2]);
     m_Controls->m_XtransBox->setValue(parameters.m_FiberGen.m_Translation[0]);
     m_Controls->m_YtransBox->setValue(parameters.m_FiberGen.m_Translation[1]);
     m_Controls->m_ZtransBox->setValue(parameters.m_FiberGen.m_Translation[2]);
     m_Controls->m_XscaleBox->setValue(parameters.m_FiberGen.m_Scale[0]);
     m_Controls->m_YscaleBox->setValue(parameters.m_FiberGen.m_Scale[1]);
     m_Controls->m_ZscaleBox->setValue(parameters.m_FiberGen.m_Scale[2]);
 
     // image generation parameters
     m_Controls->m_SizeX->setValue(parameters.m_SignalGen.m_ImageRegion.GetSize(0));
     m_Controls->m_SizeY->setValue(parameters.m_SignalGen.m_ImageRegion.GetSize(1));
     m_Controls->m_SizeZ->setValue(parameters.m_SignalGen.m_ImageRegion.GetSize(2));
     m_Controls->m_SpacingX->setValue(parameters.m_SignalGen.m_ImageSpacing[0]);
     m_Controls->m_SpacingY->setValue(parameters.m_SignalGen.m_ImageSpacing[1]);
     m_Controls->m_SpacingZ->setValue(parameters.m_SignalGen.m_ImageSpacing[2]);
     m_Controls->m_NumGradientsBox->setValue(parameters.m_SignalGen.GetNumWeightedVolumes());
     m_Controls->m_BvalueBox->setValue(parameters.m_SignalGen.m_Bvalue);
     m_Controls->m_SignalScaleBox->setValue(parameters.m_SignalGen.m_SignalScale);
     m_Controls->m_TEbox->setValue(parameters.m_SignalGen.m_tEcho);
     m_Controls->m_LineReadoutTimeBox->setValue(parameters.m_SignalGen.m_tLine);
     m_Controls->m_T2starBox->setValue(parameters.m_SignalGen.m_tInhom);
     m_Controls->m_FiberRadius->setValue(parameters.m_SignalGen.m_AxonRadius);
     m_Controls->m_RelaxationBox->setChecked(parameters.m_SignalGen.m_DoSimulateRelaxation);
     m_Controls->m_EnforcePureFiberVoxelsBox->setChecked(parameters.m_SignalGen.m_DoDisablePartialVolume);
 
     if (parameters.m_NoiseModel!=NULL)
     {
         m_Controls->m_AddNoise->setChecked(parameters.m_Misc.m_CheckAddNoiseBox);
         if (dynamic_cast<mitk::RicianNoiseModel<double>*>(parameters.m_NoiseModel))
             m_Controls->m_NoiseDistributionBox->setCurrentIndex(0);
         else if (dynamic_cast<mitk::ChiSquareNoiseModel<double>*>(parameters.m_NoiseModel))
             m_Controls->m_NoiseDistributionBox->setCurrentIndex(1);
         m_Controls->m_NoiseLevel->setValue(parameters.m_NoiseModel->GetNoiseVariance());
     }
     else
         m_Controls->m_AddNoise->setChecked(false);
 
     m_Controls->m_VolumeFractionsBox->setChecked(parameters.m_Misc.m_CheckOutputVolumeFractionsBox);
     m_Controls->m_AdvancedOptionsBox_2->setChecked(parameters.m_Misc.m_CheckAdvancedSignalOptionsBox);
     m_Controls->m_AddGhosts->setChecked(parameters.m_Misc.m_CheckAddGhostsBox);
     m_Controls->m_AddAliasing->setChecked(parameters.m_Misc.m_CheckAddAliasingBox);
     m_Controls->m_AddDistortions->setChecked(parameters.m_Misc.m_CheckAddDistortionsBox);
     m_Controls->m_AddSpikes->setChecked(parameters.m_Misc.m_CheckAddSpikesBox);
     m_Controls->m_AddEddy->setChecked(parameters.m_Misc.m_CheckAddEddyCurrentsBox);
 
     m_Controls->m_kOffsetBox->setValue(parameters.m_SignalGen.m_KspaceLineOffset);
     m_Controls->m_WrapBox->setValue(100*(1-parameters.m_SignalGen.m_CroppingFactor));
     m_Controls->m_SpikeNumBox->setValue(parameters.m_SignalGen.m_Spikes);
     m_Controls->m_SpikeScaleBox->setValue(parameters.m_SignalGen.m_SpikeAmplitude);
     m_Controls->m_EddyGradientStrength->setValue(parameters.m_SignalGen.m_EddyStrength);
     m_Controls->m_AddGibbsRinging->setChecked(parameters.m_SignalGen.m_DoAddGibbsRinging);
     m_Controls->m_AddMotion->setChecked(parameters.m_SignalGen.m_DoAddMotion);
     m_Controls->m_RandomMotion->setChecked(parameters.m_SignalGen.m_DoRandomizeMotion);
     m_Controls->m_MaxTranslationBoxX->setValue(parameters.m_SignalGen.m_Translation[0]);
     m_Controls->m_MaxTranslationBoxY->setValue(parameters.m_SignalGen.m_Translation[1]);
     m_Controls->m_MaxTranslationBoxZ->setValue(parameters.m_SignalGen.m_Translation[2]);
     m_Controls->m_MaxRotationBoxX->setValue(parameters.m_SignalGen.m_Rotation[0]);
     m_Controls->m_MaxRotationBoxY->setValue(parameters.m_SignalGen.m_Rotation[1]);
     m_Controls->m_MaxRotationBoxZ->setValue(parameters.m_SignalGen.m_Rotation[2]);
     m_Controls->m_DiffusionDirectionBox->setCurrentIndex(parameters.m_SignalGen.m_DiffusionDirectionMode);
     m_Controls->m_SeparationAngleBox->setValue(parameters.m_SignalGen.m_FiberSeparationThreshold);
 
     m_Controls->m_Compartment1Box->setCurrentIndex(0);
     m_Controls->m_Compartment2Box->setCurrentIndex(0);
     m_Controls->m_Compartment3Box->setCurrentIndex(0);
     m_Controls->m_Compartment4Box->setCurrentIndex(0);
 
     for (unsigned int i=0; i<parameters.m_FiberModelList.size()+parameters.m_NonFiberModelList.size(); i++)
     {
         mitk::DiffusionSignalModel<ScalarType>* signalModel = NULL;
         if (i<parameters.m_FiberModelList.size())
             signalModel = parameters.m_FiberModelList.at(i);
         else
             signalModel = parameters.m_NonFiberModelList.at(i-parameters.m_FiberModelList.size());
 
         switch (signalModel->m_CompartmentId)
         {
         case 1:
         {
             if (dynamic_cast<mitk::StickModel<>*>(signalModel))
             {
                 mitk::StickModel<>* model = dynamic_cast<mitk::StickModel<>*>(signalModel);
                 m_Controls->m_StickWidget1->SetT2(model->GetT2());
                 m_Controls->m_StickWidget1->SetD(model->GetDiffusivity());
                 m_Controls->m_Compartment1Box->setCurrentIndex(0);
                 break;
             }
             else if (dynamic_cast<mitk::TensorModel<>*>(signalModel))
             {
                 mitk::TensorModel<>* model = dynamic_cast<mitk::TensorModel<>*>(signalModel);
                 m_Controls->m_TensorWidget1->SetT2(model->GetT2());
                 m_Controls->m_TensorWidget1->SetD1(model->GetDiffusivity1());
                 m_Controls->m_TensorWidget1->SetD2(model->GetDiffusivity2());
                 m_Controls->m_TensorWidget1->SetD3(model->GetDiffusivity3());
                 m_Controls->m_Compartment1Box->setCurrentIndex(2);
                 break;
             }
             else if (dynamic_cast<mitk::RawShModel<>*>(signalModel))
             {
                 mitk::RawShModel<>* model = dynamic_cast<mitk::RawShModel<>*>(signalModel);
                 m_Controls->m_PrototypeWidget1->SetNumberOfSamples(model->GetMaxNumKernels());
                 m_Controls->m_PrototypeWidget1->SetMinFa(model->GetFaRange().first);
                 m_Controls->m_PrototypeWidget1->SetMaxFa(model->GetFaRange().second);
                 m_Controls->m_PrototypeWidget1->SetMinAdc(model->GetAdcRange().first);
                 m_Controls->m_PrototypeWidget1->SetMaxAdc(model->GetAdcRange().second);
                 m_Controls->m_Compartment1Box->setCurrentIndex(3);
                 break;
             }
             break;
         }
         case 2:
         {
             if (dynamic_cast<mitk::StickModel<>*>(signalModel))
             {
                 mitk::StickModel<>* model = dynamic_cast<mitk::StickModel<>*>(signalModel);
                 m_Controls->m_StickWidget2->SetT2(model->GetT2());
                 m_Controls->m_StickWidget2->SetD(model->GetDiffusivity());
                 m_Controls->m_Compartment2Box->setCurrentIndex(1);
                 break;
             }
             else if (dynamic_cast<mitk::TensorModel<>*>(signalModel))
             {
                 mitk::TensorModel<>* model = dynamic_cast<mitk::TensorModel<>*>(signalModel);
                 m_Controls->m_TensorWidget2->SetT2(model->GetT2());
                 m_Controls->m_TensorWidget2->SetD1(model->GetDiffusivity1());
                 m_Controls->m_TensorWidget2->SetD2(model->GetDiffusivity2());
                 m_Controls->m_TensorWidget2->SetD3(model->GetDiffusivity3());
                 m_Controls->m_Compartment2Box->setCurrentIndex(3);
                 break;
             }
             break;
         }
         case 3:
         {
             if (dynamic_cast<mitk::BallModel<>*>(signalModel))
             {
                 mitk::BallModel<>* model = dynamic_cast<mitk::BallModel<>*>(signalModel);
                 m_Controls->m_BallWidget1->SetT2(model->GetT2());
                 m_Controls->m_BallWidget1->SetD(model->GetDiffusivity());
                 m_Controls->m_Compartment3Box->setCurrentIndex(0);
                 break;
             }
             else if (dynamic_cast<mitk::AstroStickModel<>*>(signalModel))
             {
                 mitk::AstroStickModel<>* model = dynamic_cast<mitk::AstroStickModel<>*>(signalModel);
                 m_Controls->m_AstrosticksWidget1->SetT2(model->GetT2());
                 m_Controls->m_AstrosticksWidget1->SetD(model->GetDiffusivity());
                 m_Controls->m_AstrosticksWidget1->SetRandomizeSticks(model->GetRandomizeSticks());
                 m_Controls->m_Compartment3Box->setCurrentIndex(1);
                 break;
             }
             else if (dynamic_cast<mitk::DotModel<>*>(signalModel))
             {
                 mitk::DotModel<>* model = dynamic_cast<mitk::DotModel<>*>(signalModel);
                 m_Controls->m_DotWidget1->SetT2(model->GetT2());
                 m_Controls->m_Compartment3Box->setCurrentIndex(2);
                 break;
             }
             else if (dynamic_cast<mitk::RawShModel<>*>(signalModel))
             {
                 mitk::RawShModel<>* model = dynamic_cast<mitk::RawShModel<>*>(signalModel);
                 m_Controls->m_PrototypeWidget3->SetNumberOfSamples(model->GetMaxNumKernels());
                 m_Controls->m_PrototypeWidget3->SetMinFa(model->GetFaRange().first);
                 m_Controls->m_PrototypeWidget3->SetMaxFa(model->GetFaRange().second);
                 m_Controls->m_PrototypeWidget3->SetMinAdc(model->GetAdcRange().first);
                 m_Controls->m_PrototypeWidget3->SetMaxAdc(model->GetAdcRange().second);
                 m_Controls->m_Compartment3Box->setCurrentIndex(3);
                 break;
             }
             break;
         }
         case 4:
         {
             if (dynamic_cast<mitk::BallModel<>*>(signalModel))
             {
                 mitk::BallModel<>* model = dynamic_cast<mitk::BallModel<>*>(signalModel);
                 m_Controls->m_BallWidget2->SetT2(model->GetT2());
                 m_Controls->m_BallWidget2->SetD(model->GetDiffusivity());
                 m_Controls->m_Compartment4Box->setCurrentIndex(1);
                 break;
             }
             else if (dynamic_cast<mitk::AstroStickModel<>*>(signalModel))
             {
                 mitk::AstroStickModel<>* model = dynamic_cast<mitk::AstroStickModel<>*>(signalModel);
                 m_Controls->m_AstrosticksWidget2->SetT2(model->GetT2());
                 m_Controls->m_AstrosticksWidget2->SetD(model->GetDiffusivity());
                 m_Controls->m_AstrosticksWidget2->SetRandomizeSticks(model->GetRandomizeSticks());
                 m_Controls->m_Compartment4Box->setCurrentIndex(2);
                 break;
             }
             else if (dynamic_cast<mitk::DotModel<>*>(signalModel))
             {
                 mitk::DotModel<>* model = dynamic_cast<mitk::DotModel<>*>(signalModel);
                 m_Controls->m_DotWidget2->SetT2(model->GetT2());
                 m_Controls->m_Compartment4Box->setCurrentIndex(3);
                 break;
             }
             else if (dynamic_cast<mitk::RawShModel<>*>(signalModel))
             {
                 mitk::RawShModel<>* model = dynamic_cast<mitk::RawShModel<>*>(signalModel);
                 m_Controls->m_PrototypeWidget4->SetNumberOfSamples(model->GetMaxNumKernels());
                 m_Controls->m_PrototypeWidget4->SetMinFa(model->GetFaRange().first);
                 m_Controls->m_PrototypeWidget4->SetMaxFa(model->GetFaRange().second);
                 m_Controls->m_PrototypeWidget4->SetMinAdc(model->GetAdcRange().first);
                 m_Controls->m_PrototypeWidget4->SetMaxAdc(model->GetAdcRange().second);
                 m_Controls->m_Compartment4Box->setCurrentIndex(4);
                 break;
             }
             break;
         }
         }
     }
 }
 
 void QmitkFiberfoxView::ShowAdvancedOptions(int state)
 {
     if (state)
     {
         m_Controls->m_AdvancedFiberOptionsFrame->setVisible(true);
         m_Controls->m_AdvancedSignalOptionsFrame->setVisible(true);
         m_Controls->m_AdvancedOptionsBox->setChecked(true);
         m_Controls->m_AdvancedOptionsBox_2->setChecked(true);
     }
     else
     {
         m_Controls->m_AdvancedFiberOptionsFrame->setVisible(false);
         m_Controls->m_AdvancedSignalOptionsFrame->setVisible(false);
         m_Controls->m_AdvancedOptionsBox->setChecked(false);
         m_Controls->m_AdvancedOptionsBox_2->setChecked(false);
     }
 }
 
 void QmitkFiberfoxView::Comp1ModelFrameVisibility(int index)
 {
     m_Controls->m_StickWidget1->setVisible(false);
     m_Controls->m_ZeppelinWidget1->setVisible(false);
     m_Controls->m_TensorWidget1->setVisible(false);
     m_Controls->m_PrototypeWidget1->setVisible(false);
 
     switch (index)
     {
     case 0:
         m_Controls->m_StickWidget1->setVisible(true);
         break;
     case 1:
         m_Controls->m_ZeppelinWidget1->setVisible(true);
         break;
     case 2:
         m_Controls->m_TensorWidget1->setVisible(true);
         break;
     case 3:
         m_Controls->m_PrototypeWidget1->setVisible(true);
         break;
     }
 }
 
 void QmitkFiberfoxView::Comp2ModelFrameVisibility(int index)
 {
     m_Controls->m_StickWidget2->setVisible(false);
     m_Controls->m_ZeppelinWidget2->setVisible(false);
     m_Controls->m_TensorWidget2->setVisible(false);
 
     switch (index)
     {
     case 0:
         break;
     case 1:
         m_Controls->m_StickWidget2->setVisible(true);
         break;
     case 2:
         m_Controls->m_ZeppelinWidget2->setVisible(true);
         break;
     case 3:
         m_Controls->m_TensorWidget2->setVisible(true);
         break;
     }
 }
 
 void QmitkFiberfoxView::Comp3ModelFrameVisibility(int index)
 {
     m_Controls->m_BallWidget1->setVisible(false);
     m_Controls->m_AstrosticksWidget1->setVisible(false);
     m_Controls->m_DotWidget1->setVisible(false);
     m_Controls->m_PrototypeWidget3->setVisible(false);
 
     switch (index)
     {
     case 0:
         m_Controls->m_BallWidget1->setVisible(true);
         break;
     case 1:
         m_Controls->m_AstrosticksWidget1->setVisible(true);
         break;
     case 2:
         m_Controls->m_DotWidget1->setVisible(true);
         break;
     case 3:
         m_Controls->m_PrototypeWidget3->setVisible(true);
         break;
     }
 }
 
 void QmitkFiberfoxView::Comp4ModelFrameVisibility(int index)
 {
     m_Controls->m_BallWidget2->setVisible(false);
     m_Controls->m_AstrosticksWidget2->setVisible(false);
     m_Controls->m_DotWidget2->setVisible(false);
     m_Controls->m_PrototypeWidget4->setVisible(false);
     m_Controls->m_Comp4FractionFrame->setVisible(false);
 
     switch (index)
     {
     case 0:
         break;
     case 1:
         m_Controls->m_BallWidget2->setVisible(true);
         m_Controls->m_Comp4FractionFrame->setVisible(true);
         break;
     case 2:
         m_Controls->m_AstrosticksWidget2->setVisible(true);
         m_Controls->m_Comp4FractionFrame->setVisible(true);
         break;
     case 3:
         m_Controls->m_DotWidget2->setVisible(true);
         m_Controls->m_Comp4FractionFrame->setVisible(true);
         break;
     case 4:
         m_Controls->m_PrototypeWidget4->setVisible(true);
         m_Controls->m_Comp4FractionFrame->setVisible(true);
         break;
     }
 }
 
 void QmitkFiberfoxView::OnConstantRadius(int value)
 {
     if (value>0 && m_Controls->m_RealTimeFibers->isChecked())
         GenerateFibers();
 }
 
 void QmitkFiberfoxView::OnAddMotion(int value)
 {
     if (value>0)
         m_Controls->m_MotionArtifactFrame->setVisible(true);
     else
         m_Controls->m_MotionArtifactFrame->setVisible(false);
 }
 
 void QmitkFiberfoxView::OnAddAliasing(int value)
 {
     if (value>0)
         m_Controls->m_AliasingFrame->setVisible(true);
     else
         m_Controls->m_AliasingFrame->setVisible(false);
 }
 
 void QmitkFiberfoxView::OnAddSpikes(int value)
 {
     if (value>0)
         m_Controls->m_SpikeFrame->setVisible(true);
     else
         m_Controls->m_SpikeFrame->setVisible(false);
 }
 
 void QmitkFiberfoxView::OnAddEddy(int value)
 {
     if (value>0)
         m_Controls->m_EddyFrame->setVisible(true);
     else
         m_Controls->m_EddyFrame->setVisible(false);
 }
 
 void QmitkFiberfoxView::OnAddDistortions(int value)
 {
     if (value>0)
         m_Controls->m_DistortionsFrame->setVisible(true);
     else
         m_Controls->m_DistortionsFrame->setVisible(false);
 }
 
 void QmitkFiberfoxView::OnAddGhosts(int value)
 {
     if (value>0)
         m_Controls->m_GhostFrame->setVisible(true);
     else
         m_Controls->m_GhostFrame->setVisible(false);
 }
 
 void QmitkFiberfoxView::OnAddNoise(int value)
 {
     if (value>0)
         m_Controls->m_NoiseFrame->setVisible(true);
     else
         m_Controls->m_NoiseFrame->setVisible(false);
 }
 
 void QmitkFiberfoxView::OnDistributionChanged(int value)
 {
     if (value==1)
         m_Controls->m_VarianceBox->setVisible(true);
     else
         m_Controls->m_VarianceBox->setVisible(false);
 
     if (m_Controls->m_RealTimeFibers->isChecked())
         GenerateFibers();
 }
 
 void QmitkFiberfoxView::OnVarianceChanged(double)
 {
     if (m_Controls->m_RealTimeFibers->isChecked())
         GenerateFibers();
 }
 
 void QmitkFiberfoxView::OnFiberDensityChanged(int)
 {
     if (m_Controls->m_RealTimeFibers->isChecked())
         GenerateFibers();
 }
 
 void QmitkFiberfoxView::OnFiberSamplingChanged(double)
 {
     if (m_Controls->m_RealTimeFibers->isChecked())
         GenerateFibers();
 }
 
 void QmitkFiberfoxView::OnTensionChanged(double)
 {
     if (m_Controls->m_RealTimeFibers->isChecked())
         GenerateFibers();
 }
 
 void QmitkFiberfoxView::OnContinuityChanged(double)
 {
     if (m_Controls->m_RealTimeFibers->isChecked())
         GenerateFibers();
 }
 
 void QmitkFiberfoxView::OnBiasChanged(double)
 {
     if (m_Controls->m_RealTimeFibers->isChecked())
         GenerateFibers();
 }
 
 void QmitkFiberfoxView::AlignOnGrid()
 {
     for (unsigned int i=0; i<m_SelectedFiducials.size(); i++)
     {
         mitk::PlanarEllipse::Pointer pe = dynamic_cast<mitk::PlanarEllipse*>(m_SelectedFiducials.at(i)->GetData());
         mitk::Point3D wc0 = pe->GetWorldControlPoint(0);
 
         mitk::DataStorage::SetOfObjects::ConstPointer parentFibs = GetDataStorage()->GetSources(m_SelectedFiducials.at(i));
         for( mitk::DataStorage::SetOfObjects::const_iterator it = parentFibs->begin(); it != parentFibs->end(); ++it )
         {
             mitk::DataNode::Pointer pFibNode = *it;
             if ( pFibNode.IsNotNull() && dynamic_cast<mitk::FiberBundle*>(pFibNode->GetData()) )
             {
                 mitk::DataStorage::SetOfObjects::ConstPointer parentImgs = GetDataStorage()->GetSources(pFibNode);
                 for( mitk::DataStorage::SetOfObjects::const_iterator it2 = parentImgs->begin(); it2 != parentImgs->end(); ++it2 )
                 {
                     mitk::DataNode::Pointer pImgNode = *it2;
                     if ( pImgNode.IsNotNull() && dynamic_cast<mitk::Image*>(pImgNode->GetData()) )
                     {
                         mitk::Image::Pointer img = dynamic_cast<mitk::Image*>(pImgNode->GetData());
                         mitk::BaseGeometry::Pointer geom = img->GetGeometry();
                         itk::Index<3> idx;
                         geom->WorldToIndex(wc0, idx);
 
                         mitk::Point3D cIdx; cIdx[0]=idx[0]; cIdx[1]=idx[1]; cIdx[2]=idx[2];
                         mitk::Point3D world;
                         geom->IndexToWorld(cIdx,world);
 
                         mitk::Vector3D trans = world - wc0;
                         pe->GetGeometry()->Translate(trans);
 
                         break;
                     }
                 }
                 break;
             }
         }
     }
 
     for(unsigned int i=0; i<m_SelectedBundles2.size(); i++ )
     {
         mitk::DataNode::Pointer fibNode = m_SelectedBundles2.at(i);
 
         mitk::DataStorage::SetOfObjects::ConstPointer sources = GetDataStorage()->GetSources(fibNode);
         for( mitk::DataStorage::SetOfObjects::const_iterator it = sources->begin(); it != sources->end(); ++it )
         {
             mitk::DataNode::Pointer imgNode = *it;
             if ( imgNode.IsNotNull() && dynamic_cast<mitk::Image*>(imgNode->GetData()) )
             {
                 mitk::DataStorage::SetOfObjects::ConstPointer derivations = GetDataStorage()->GetDerivations(fibNode);
                 for( mitk::DataStorage::SetOfObjects::const_iterator it2 = derivations->begin(); it2 != derivations->end(); ++it2 )
                 {
                     mitk::DataNode::Pointer fiducialNode = *it2;
                     if ( fiducialNode.IsNotNull() && dynamic_cast<mitk::PlanarEllipse*>(fiducialNode->GetData()) )
                     {
                         mitk::PlanarEllipse::Pointer pe = dynamic_cast<mitk::PlanarEllipse*>(fiducialNode->GetData());
                         mitk::Point3D wc0 = pe->GetWorldControlPoint(0);
 
                         mitk::Image::Pointer img = dynamic_cast<mitk::Image*>(imgNode->GetData());
                         mitk::BaseGeometry::Pointer geom = img->GetGeometry();
                         itk::Index<3> idx;
                         geom->WorldToIndex(wc0, idx);
                         mitk::Point3D cIdx; cIdx[0]=idx[0]; cIdx[1]=idx[1]; cIdx[2]=idx[2];
                         mitk::Point3D world;
                         geom->IndexToWorld(cIdx,world);
 
                         mitk::Vector3D trans = world - wc0;
                         pe->GetGeometry()->Translate(trans);
                     }
                 }
 
                 break;
             }
         }
     }
 
     for(unsigned int i=0; i<m_SelectedImages.size(); i++ )
     {
         mitk::Image::Pointer img = dynamic_cast<mitk::Image*>(m_SelectedImages.at(i)->GetData());
 
         mitk::DataStorage::SetOfObjects::ConstPointer derivations = GetDataStorage()->GetDerivations(m_SelectedImages.at(i));
         for( mitk::DataStorage::SetOfObjects::const_iterator it = derivations->begin(); it != derivations->end(); ++it )
         {
             mitk::DataNode::Pointer fibNode = *it;
             if ( fibNode.IsNotNull() && dynamic_cast<mitk::FiberBundle*>(fibNode->GetData()) )
             {
                 mitk::DataStorage::SetOfObjects::ConstPointer derivations2 = GetDataStorage()->GetDerivations(fibNode);
                 for( mitk::DataStorage::SetOfObjects::const_iterator it2 = derivations2->begin(); it2 != derivations2->end(); ++it2 )
                 {
                     mitk::DataNode::Pointer fiducialNode = *it2;
                     if ( fiducialNode.IsNotNull() && dynamic_cast<mitk::PlanarEllipse*>(fiducialNode->GetData()) )
                     {
                         mitk::PlanarEllipse::Pointer pe = dynamic_cast<mitk::PlanarEllipse*>(fiducialNode->GetData());
                         mitk::Point3D wc0 = pe->GetWorldControlPoint(0);
 
                         mitk::BaseGeometry::Pointer geom = img->GetGeometry();
                         itk::Index<3> idx;
                         geom->WorldToIndex(wc0, idx);
                         mitk::Point3D cIdx; cIdx[0]=idx[0]; cIdx[1]=idx[1]; cIdx[2]=idx[2];
                         mitk::Point3D world;
                         geom->IndexToWorld(cIdx,world);
 
                         mitk::Vector3D trans = world - wc0;
                         pe->GetGeometry()->Translate(trans);
                     }
                 }
             }
         }
     }
 
     mitk::RenderingManager::GetInstance()->RequestUpdateAll();
     if (m_Controls->m_RealTimeFibers->isChecked())
         GenerateFibers();
 }
 
 void QmitkFiberfoxView::OnFlipButton()
 {
     if (m_SelectedFiducial.IsNull())
         return;
 
     std::map<mitk::DataNode*, QmitkPlanarFigureData>::iterator it = m_DataNodeToPlanarFigureData.find(m_SelectedFiducial.GetPointer());
     if( it != m_DataNodeToPlanarFigureData.end() )
     {
         QmitkPlanarFigureData& data = it->second;
         data.m_Flipped += 1;
         data.m_Flipped %= 2;
     }
 
     if (m_Controls->m_RealTimeFibers->isChecked())
         GenerateFibers();
 }
 
 QmitkFiberfoxView::GradientListType QmitkFiberfoxView::GenerateHalfShell(int NPoints)
 {
     NPoints *= 2;
     GradientListType pointshell;
 
     int numB0 = NPoints/20;
     if (numB0==0)
         numB0=1;
     GradientType g;
     g.Fill(0.0);
     for (int i=0; i<numB0; i++)
         pointshell.push_back(g);
 
     if (NPoints==0)
         return pointshell;
 
     vnl_vector<double> theta; theta.set_size(NPoints);
     vnl_vector<double> phi; phi.set_size(NPoints);
     double C = sqrt(4*M_PI);
     phi(0) = 0.0;
     phi(NPoints-1) = 0.0;
     for(int i=0; i<NPoints; i++)
     {
         theta(i) = acos(-1.0+2.0*i/(NPoints-1.0)) - M_PI / 2.0;
         if( i>0 && i<NPoints-1)
         {
             phi(i) = (phi(i-1) + C /
                       sqrt(NPoints*(1-(-1.0+2.0*i/(NPoints-1.0))*(-1.0+2.0*i/(NPoints-1.0)))));
             // % (2*DIST_POINTSHELL_PI);
         }
     }
 
     for(int i=0; i<NPoints; i++)
     {
         g[2] = sin(theta(i));
         if (g[2]<0)
             continue;
         g[0] = cos(theta(i)) * cos(phi(i));
         g[1] = cos(theta(i)) * sin(phi(i));
         pointshell.push_back(g);
     }
 
     return pointshell;
 }
 
 template<int ndirs>
 std::vector<itk::Vector<double,3> > QmitkFiberfoxView::MakeGradientList()
 {
     std::vector<itk::Vector<double,3> > retval;
     vnl_matrix_fixed<double, 3, ndirs>* U =
             itk::PointShell<ndirs, vnl_matrix_fixed<double, 3, ndirs> >::DistributePointShell();
 
 
     // Add 0 vector for B0
     int numB0 = ndirs/10;
     if (numB0==0)
         numB0=1;
     itk::Vector<double,3> v;
     v.Fill(0.0);
     for (int i=0; i<numB0; i++)
     {
         retval.push_back(v);
     }
 
     for(int i=0; i<ndirs;i++)
     {
         itk::Vector<double,3> v;
         v[0] = U->get(0,i); v[1] = U->get(1,i); v[2] = U->get(2,i);
         retval.push_back(v);
     }
 
     return retval;
 }
 
 void QmitkFiberfoxView::OnAddBundle()
 {
-    if (m_SelectedImage.IsNull())
+    if (m_SelectedImageNode.IsNull())
         return;
 
-    mitk::DataStorage::SetOfObjects::ConstPointer children = GetDataStorage()->GetDerivations(m_SelectedImage);
+    mitk::DataStorage::SetOfObjects::ConstPointer children = GetDataStorage()->GetDerivations(m_SelectedImageNode);
 
     mitk::FiberBundle::Pointer bundle = mitk::FiberBundle::New();
     mitk::DataNode::Pointer node = mitk::DataNode::New();
     node->SetData( bundle );
     QString name = QString("Bundle_%1").arg(children->size());
     node->SetName(name.toStdString());
     m_SelectedBundles.push_back(node);
     UpdateGui();
 
-    GetDataStorage()->Add(node, m_SelectedImage);
+    GetDataStorage()->Add(node, m_SelectedImageNode);
 }
 
 void QmitkFiberfoxView::OnDrawROI()
 {
     if (m_SelectedBundles.empty())
         OnAddBundle();
     if (m_SelectedBundles.empty())
         return;
 
     mitk::DataStorage::SetOfObjects::ConstPointer children = GetDataStorage()->GetDerivations(m_SelectedBundles.at(0));
 
     mitk::PlanarEllipse::Pointer figure = mitk::PlanarEllipse::New();
 
     mitk::DataNode::Pointer node = mitk::DataNode::New();
     node->SetData( figure );
     node->SetBoolProperty("planarfigure.3drendering", true);
     node->SetBoolProperty("planarfigure.3drendering.fill", true);
 
     QList<mitk::DataNode::Pointer> nodes = this->GetDataManagerSelection();
     for( int i=0; i<nodes.size(); i++)
         nodes.at(i)->SetSelected(false);
 
     m_SelectedFiducial = node;
 
     QString name = QString("Fiducial_%1").arg(children->size());
     node->SetName(name.toStdString());
     node->SetSelected(true);
 
     this->DisableCrosshairNavigation();
 
     mitk::PlanarFigureInteractor::Pointer figureInteractor = dynamic_cast<mitk::PlanarFigureInteractor*>(node->GetDataInteractor().GetPointer());
     if(figureInteractor.IsNull())
     {
         figureInteractor = mitk::PlanarFigureInteractor::New();
         us::Module* planarFigureModule = us::ModuleRegistry::GetModule( "MitkPlanarFigure" );
         figureInteractor->LoadStateMachine("PlanarFigureInteraction.xml", planarFigureModule );
         figureInteractor->SetEventConfig( "PlanarFigureConfig.xml", planarFigureModule );
         figureInteractor->SetDataNode( node );
     }
 
     UpdateGui();
     GetDataStorage()->Add(node, m_SelectedBundles.at(0));
 }
 
 bool CompareLayer(mitk::DataNode::Pointer i,mitk::DataNode::Pointer j)
 {
     int li = -1;
     i->GetPropertyValue("layer", li);
     int lj = -1;
     j->GetPropertyValue("layer", lj);
     return li<lj;
 }
 
 void QmitkFiberfoxView::GenerateFibers()
 {
     if (m_SelectedBundles.empty())
     {
         if (m_SelectedFiducial.IsNull())
             return;
 
         mitk::DataStorage::SetOfObjects::ConstPointer parents = GetDataStorage()->GetSources(m_SelectedFiducial);
         for( mitk::DataStorage::SetOfObjects::const_iterator it = parents->begin(); it != parents->end(); ++it )
             if(dynamic_cast<mitk::FiberBundle*>((*it)->GetData()))
                 m_SelectedBundles.push_back(*it);
 
         if (m_SelectedBundles.empty())
             return;
     }
 
     FiberfoxParameters<double> parameters = UpdateImageParameters<double>();
 
     for (unsigned int i=0; i<m_SelectedBundles.size(); i++)
     {
         mitk::DataStorage::SetOfObjects::ConstPointer children = GetDataStorage()->GetDerivations(m_SelectedBundles.at(i));
         std::vector< mitk::DataNode::Pointer > childVector;
         for( mitk::DataStorage::SetOfObjects::const_iterator it = children->begin(); it != children->end(); ++it )
             childVector.push_back(*it);
         sort(childVector.begin(), childVector.end(), CompareLayer);
 
         vector< mitk::PlanarEllipse::Pointer > fib;
         vector< unsigned int > flip;
         float radius = 1;
         int count = 0;
         for( std::vector< mitk::DataNode::Pointer >::const_iterator it = childVector.begin(); it != childVector.end(); ++it )
         {
             mitk::DataNode::Pointer node = *it;
 
             if ( node.IsNotNull() && dynamic_cast<mitk::PlanarEllipse*>(node->GetData()) )
             {
                 mitk::PlanarEllipse* ellipse = dynamic_cast<mitk::PlanarEllipse*>(node->GetData());
                 if (m_Controls->m_ConstantRadiusBox->isChecked())
                 {
                     ellipse->SetTreatAsCircle(true);
                     mitk::Point2D c = ellipse->GetControlPoint(0);
                     mitk::Point2D p = ellipse->GetControlPoint(1);
                     mitk::Vector2D v = p-c;
                     if (count==0)
                     {
                         radius = v.GetVnlVector().magnitude();
                         ellipse->SetControlPoint(1, p);
                         ellipse->Modified();
                     }
                     else
                     {
                         v.Normalize();
                         v *= radius;
                         ellipse->SetControlPoint(1, c+v);
                         ellipse->Modified();
                     }
                 }
                 fib.push_back(ellipse);
 
                 std::map<mitk::DataNode*, QmitkPlanarFigureData>::iterator it = m_DataNodeToPlanarFigureData.find(node.GetPointer());
                 if( it != m_DataNodeToPlanarFigureData.end() )
                 {
                     QmitkPlanarFigureData& data = it->second;
                     flip.push_back(data.m_Flipped);
                 }
                 else
                     flip.push_back(0);
             }
             count++;
         }
         if (fib.size()>1)
         {
             parameters.m_FiberGen.m_Fiducials.push_back(fib);
             parameters.m_FiberGen.m_FlipList.push_back(flip);
         }
         else if (fib.size()>0)
             m_SelectedBundles.at(i)->SetData( mitk::FiberBundle::New() );
 
         mitk::RenderingManager::GetInstance()->RequestUpdateAll();
     }
 
     itk::FibersFromPlanarFiguresFilter::Pointer filter = itk::FibersFromPlanarFiguresFilter::New();
     filter->SetParameters(parameters.m_FiberGen);
     filter->Update();
     vector< mitk::FiberBundle::Pointer > fiberBundles = filter->GetFiberBundles();
 
     for (unsigned int i=0; i<fiberBundles.size(); i++)
     {
         m_SelectedBundles.at(i)->SetData( fiberBundles.at(i) );
         if (fiberBundles.at(i)->GetNumFibers()>50000)
             m_SelectedBundles.at(i)->SetVisibility(false);
     }
 
     mitk::RenderingManager::GetInstance()->RequestUpdateAll();
 }
 
 void QmitkFiberfoxView::GenerateImage()
 {
     if (m_Controls->m_FiberBundleComboBox->GetSelectedNode().IsNull() && m_Controls->m_TemplateComboBox->GetSelectedNode().IsNull())
     {
         mitk::Image::Pointer image = mitk::ImageGenerator::GenerateGradientImage<unsigned int>(
                     m_Controls->m_SizeX->value(),
                     m_Controls->m_SizeY->value(),
                     m_Controls->m_SizeZ->value(),
                     m_Controls->m_SpacingX->value(),
                     m_Controls->m_SpacingY->value(),
                     m_Controls->m_SpacingZ->value());
 
         mitk::DataNode::Pointer node = mitk::DataNode::New();
         node->SetData( image );
         node->SetName("Dummy");
         unsigned int window = m_Controls->m_SizeX->value()*m_Controls->m_SizeY->value()*m_Controls->m_SizeZ->value();
         unsigned int level = window/2;
         mitk::LevelWindow lw; lw.SetLevelWindow(level, window);
         node->SetProperty( "levelwindow", mitk::LevelWindowProperty::New( lw ) );
         GetDataStorage()->Add(node);
-        m_SelectedImage = node;
+        m_SelectedImageNode = node;
 
         mitk::BaseData::Pointer basedata = node->GetData();
         if (basedata.IsNotNull())
         {
             mitk::RenderingManager::GetInstance()->InitializeViews( basedata->GetTimeGeometry(), mitk::RenderingManager::REQUEST_UPDATE_ALL, true );
             mitk::RenderingManager::GetInstance()->RequestUpdateAll();
         }
         UpdateGui();
     }
     else if (m_Controls->m_FiberBundleComboBox->GetSelectedNode().IsNotNull())
         SimulateImageFromFibers(m_Controls->m_FiberBundleComboBox->GetSelectedNode());
     else if ( m_Controls->m_TemplateComboBox->GetSelectedNode().IsNotNull() )
         SimulateForExistingDwi(m_Controls->m_TemplateComboBox->GetSelectedNode());
 }
 
 void QmitkFiberfoxView::SimulateForExistingDwi(mitk::DataNode* imageNode)
 {
   bool isDiffusionImage( mitk::DiffusionPropertyHelper::IsDiffusionWeightedImage( dynamic_cast<mitk::Image *>(imageNode->GetData())) );
   if ( !isDiffusionImage )
   {
     return;
   }
 
     FiberfoxParameters<short> parameters = UpdateImageParameters<short>();
 
     if (parameters.m_NoiseModel==NULL &&
             parameters.m_SignalGen.m_Spikes==0 &&
             parameters.m_SignalGen.m_FrequencyMap.IsNull() &&
             parameters.m_SignalGen.m_KspaceLineOffset<=0.000001 &&
             !parameters.m_SignalGen.m_DoAddGibbsRinging &&
             !(parameters.m_SignalGen.m_EddyStrength>0) &&
             parameters.m_SignalGen.m_CroppingFactor>0.999)
     {
         QMessageBox::information( NULL, "Simulation cancelled", "No valid artifact enabled! Motion artifacts and relaxation effects can NOT be added to an existing diffusion weighted image.");
         return;
     }
 
     mitk::Image::Pointer diffImg = dynamic_cast<mitk::Image*>(imageNode->GetData());
 
     ItkDwiType::Pointer itkVectorImagePointer = ItkDwiType::New();
     mitk::CastToItkImage(diffImg, itkVectorImagePointer);
 
     m_ArtifactsToDwiFilter = itk::AddArtifactsToDwiImageFilter< short >::New();
     m_ArtifactsToDwiFilter->SetInput(itkVectorImagePointer);
     parameters.m_Misc.m_ParentNode = imageNode;
     m_ArtifactsToDwiFilter->SetParameters(parameters);
     m_Worker.m_FilterType = 1;
     m_Thread.start(QThread::LowestPriority);
 }
 
 void QmitkFiberfoxView::SimulateImageFromFibers(mitk::DataNode* fiberNode)
 {
     mitk::FiberBundle::Pointer fiberBundle = dynamic_cast<mitk::FiberBundle*>(fiberNode->GetData());
     if (fiberBundle->GetNumFibers()<=0)
         return;
 
     FiberfoxParameters<double> parameters = UpdateImageParameters<double>();
 
     m_TractsToDwiFilter = itk::TractsToDWIImageFilter< short >::New();
     parameters.m_Misc.m_ParentNode = fiberNode;
     if (m_Controls->m_TemplateComboBox->GetSelectedNode().IsNotNull() && mitk::DiffusionPropertyHelper::IsDiffusionWeightedImage( dynamic_cast<mitk::Image*>(m_Controls->m_TemplateComboBox->GetSelectedNode()->GetData())))
     {
         bool first = true;
         bool ok = true;
         mitk::Image::Pointer diffImg = dynamic_cast<mitk::Image*>(m_Controls->m_TemplateComboBox->GetSelectedNode()->GetData());
         itk::Image< itk::DiffusionTensor3D< double >, 3 >::Pointer tensorImage = NULL;
         const int shOrder = 2;
         typedef itk::AnalyticalDiffusionQballReconstructionImageFilter<short,short,float,shOrder,QBALL_ODFSIZE> QballFilterType;
         QballFilterType::CoefficientImageType::Pointer itkFeatureImage = NULL;
         ItkDoubleImgType::Pointer adcImage = NULL;
 
         for (unsigned int i=0; i<parameters.m_FiberModelList.size()+parameters.m_NonFiberModelList.size(); i++)
         {
             mitk::RawShModel<>* model = NULL;
             if (i<parameters.m_FiberModelList.size())
                 model = dynamic_cast<  mitk::RawShModel<>* >(parameters.m_FiberModelList.at(i));
             else
                 model = dynamic_cast<  mitk::RawShModel<>* >(parameters.m_NonFiberModelList.at(i-parameters.m_FiberModelList.size()));
 
             if (model!=0 && model->GetNumberOfKernels()<=0)
             {
                 if (first==true)
                 {
                   ItkDwiType::Pointer itkVectorImagePointer = ItkDwiType::New();
                   mitk::CastToItkImage(diffImg, itkVectorImagePointer);
 
                     typedef itk::DiffusionTensor3DReconstructionImageFilter< short, short, double > TensorReconstructionImageFilterType;
                     TensorReconstructionImageFilterType::Pointer filter = TensorReconstructionImageFilterType::New();
                     filter->SetGradientImage( static_cast<mitk::GradientDirectionsProperty*>( diffImg->GetProperty(mitk::DiffusionPropertyHelper::GRADIENTCONTAINERPROPERTYNAME.c_str()).GetPointer() )->GetGradientDirectionsContainer(), itkVectorImagePointer );
                     filter->SetBValue( static_cast<mitk::FloatProperty*>(diffImg->GetProperty(mitk::DiffusionPropertyHelper::REFERENCEBVALUEPROPERTYNAME.c_str()).GetPointer() )->GetValue() );
                     filter->Update();
                     tensorImage = filter->GetOutput();
 
                     const int NumCoeffs = (shOrder*shOrder + shOrder + 2)/2 + shOrder;
                     QballFilterType::Pointer qballfilter = QballFilterType::New();
                     qballfilter->SetGradientImage( static_cast<mitk::GradientDirectionsProperty*>( diffImg->GetProperty(mitk::DiffusionPropertyHelper::GRADIENTCONTAINERPROPERTYNAME.c_str()).GetPointer() )->GetGradientDirectionsContainer(), itkVectorImagePointer );
                     qballfilter->SetBValue( static_cast<mitk::FloatProperty*>(diffImg->GetProperty(mitk::DiffusionPropertyHelper::REFERENCEBVALUEPROPERTYNAME.c_str()).GetPointer() )->GetValue() );
                     qballfilter->SetLambda(0.006);
                     qballfilter->SetNormalizationMethod(QballFilterType::QBAR_RAW_SIGNAL);
                     qballfilter->Update();
                     itkFeatureImage = qballfilter->GetCoefficientImage();
 
                     itk::AdcImageFilter< short, double >::Pointer adcFilter = itk::AdcImageFilter< short, double >::New();
                     adcFilter->SetInput( itkVectorImagePointer );
                     adcFilter->SetGradientDirections( static_cast<mitk::GradientDirectionsProperty*>( diffImg->GetProperty(mitk::DiffusionPropertyHelper::GRADIENTCONTAINERPROPERTYNAME.c_str()).GetPointer() )->GetGradientDirectionsContainer() );
                     adcFilter->SetB_value( static_cast<mitk::FloatProperty*>(diffImg->GetProperty(mitk::DiffusionPropertyHelper::REFERENCEBVALUEPROPERTYNAME.c_str()).GetPointer() )->GetValue() );
                     adcFilter->Update();
                     adcImage = adcFilter->GetOutput();
                 }
                 ok = model->SampleKernels(diffImg, parameters.m_SignalGen.m_MaskImage, tensorImage, itkFeatureImage, adcImage);
                 if (!ok)
                     break;
             }
         }
 
         if (!ok)
         {
             QMessageBox::information( NULL, "Simulation cancelled", "No valid prototype signals could be sampled.");
             return;
         }
     }
     else if ( m_Controls->m_Compartment1Box->currentIndex()==3 || m_Controls->m_Compartment3Box->currentIndex()==3 || m_Controls->m_Compartment4Box->currentIndex()==4 )
     {
         QMessageBox::information( NULL, "Simulation cancelled", "Prototype signal but no diffusion-weighted image selected to sample signal from.");
         return;
     }
 
+    if (m_SelectedImageNode.IsNotNull())
+    {
+        ItkFloatImgType::Pointer itkImg = ItkFloatImgType::New();
+        mitk::Image::Pointer mitkImg = dynamic_cast<mitk::Image*>(m_SelectedImageNode->GetData());
+        mitk::CastToItkImage<ItkFloatImgType>(mitkImg, itkImg);
+        m_TractsToDwiFilter->SetHelperTdi(itkImg);
+    }
     m_TractsToDwiFilter->SetParameters(parameters);
     m_TractsToDwiFilter->SetFiberBundle(fiberBundle);
     m_Worker.m_FilterType = 0;
     m_Thread.start(QThread::LowestPriority);
 }
 
 void QmitkFiberfoxView::ApplyTransform()
 {
     vector< mitk::DataNode::Pointer > selectedBundles;
     for(unsigned int i=0; i<m_SelectedImages.size(); i++ )
     {
         mitk::DataStorage::SetOfObjects::ConstPointer derivations = GetDataStorage()->GetDerivations(m_SelectedImages.at(i));
         for( mitk::DataStorage::SetOfObjects::const_iterator it = derivations->begin(); it != derivations->end(); ++it )
         {
             mitk::DataNode::Pointer fibNode = *it;
             if ( fibNode.IsNotNull() && dynamic_cast<mitk::FiberBundle*>(fibNode->GetData()) )
                 selectedBundles.push_back(fibNode);
         }
     }
     if (selectedBundles.empty())
         selectedBundles = m_SelectedBundles2;
 
     if (!selectedBundles.empty())
     {
         for (std::vector<mitk::DataNode::Pointer>::const_iterator it = selectedBundles.begin(); it!=selectedBundles.end(); ++it)
         {
             mitk::FiberBundle::Pointer fib = dynamic_cast<mitk::FiberBundle*>((*it)->GetData());
             fib->RotateAroundAxis(m_Controls->m_XrotBox->value(), m_Controls->m_YrotBox->value(), m_Controls->m_ZrotBox->value());
             fib->TranslateFibers(m_Controls->m_XtransBox->value(), m_Controls->m_YtransBox->value(), m_Controls->m_ZtransBox->value());
             fib->ScaleFibers(m_Controls->m_XscaleBox->value(), m_Controls->m_YscaleBox->value(), m_Controls->m_ZscaleBox->value());
 
             // handle child fiducials
             if (m_Controls->m_IncludeFiducials->isChecked())
             {
                 mitk::DataStorage::SetOfObjects::ConstPointer derivations = GetDataStorage()->GetDerivations(*it);
                 for( mitk::DataStorage::SetOfObjects::const_iterator it2 = derivations->begin(); it2 != derivations->end(); ++it2 )
                 {
                     mitk::DataNode::Pointer fiducialNode = *it2;
                     if ( fiducialNode.IsNotNull() && dynamic_cast<mitk::PlanarEllipse*>(fiducialNode->GetData()) )
                     {
                         mitk::PlanarEllipse* pe = dynamic_cast<mitk::PlanarEllipse*>(fiducialNode->GetData());
                         mitk::BaseGeometry* geom = pe->GetGeometry();
 
                         // translate
                         mitk::Vector3D world;
                         world[0] = m_Controls->m_XtransBox->value();
                         world[1] = m_Controls->m_YtransBox->value();
                         world[2] = m_Controls->m_ZtransBox->value();
                         geom->Translate(world);
 
                         // calculate rotation matrix
                         double x = m_Controls->m_XrotBox->value()*M_PI/180;
                         double y = m_Controls->m_YrotBox->value()*M_PI/180;
                         double z = m_Controls->m_ZrotBox->value()*M_PI/180;
 
                         itk::Matrix< double, 3, 3 > rotX; rotX.SetIdentity();
                         rotX[1][1] = cos(x);
                         rotX[2][2] = rotX[1][1];
                         rotX[1][2] = -sin(x);
                         rotX[2][1] = -rotX[1][2];
 
                         itk::Matrix< double, 3, 3 > rotY; rotY.SetIdentity();
                         rotY[0][0] = cos(y);
                         rotY[2][2] = rotY[0][0];
                         rotY[0][2] = sin(y);
                         rotY[2][0] = -rotY[0][2];
 
                         itk::Matrix< double, 3, 3 > rotZ; rotZ.SetIdentity();
                         rotZ[0][0] = cos(z);
                         rotZ[1][1] = rotZ[0][0];
                         rotZ[0][1] = -sin(z);
                         rotZ[1][0] = -rotZ[0][1];
 
                         itk::Matrix< double, 3, 3 > rot = rotZ*rotY*rotX;
 
                         // transform control point coordinate into geometry translation
                         geom->SetOrigin(pe->GetWorldControlPoint(0));
                         mitk::Point2D cp; cp.Fill(0.0);
                         pe->SetControlPoint(0, cp);
 
                         // rotate fiducial
                         geom->GetIndexToWorldTransform()->SetMatrix(rot*geom->GetIndexToWorldTransform()->GetMatrix());
 
                         // implicit translation
                         mitk::Vector3D trans;
                         trans[0] = geom->GetOrigin()[0]-fib->GetGeometry()->GetCenter()[0];
                         trans[1] = geom->GetOrigin()[1]-fib->GetGeometry()->GetCenter()[1];
                         trans[2] = geom->GetOrigin()[2]-fib->GetGeometry()->GetCenter()[2];
                         mitk::Vector3D newWc = rot*trans;
                         newWc = newWc-trans;
                         geom->Translate(newWc);
 
                         pe->Modified();
                     }
                 }
             }
         }
     }
     else
     {
         for (unsigned int i=0; i<m_SelectedFiducials.size(); i++)
         {
             mitk::PlanarEllipse* pe = dynamic_cast<mitk::PlanarEllipse*>(m_SelectedFiducials.at(i)->GetData());
             mitk::BaseGeometry* geom = pe->GetGeometry();
 
             // translate
             mitk::Vector3D world;
             world[0] = m_Controls->m_XtransBox->value();
             world[1] = m_Controls->m_YtransBox->value();
             world[2] = m_Controls->m_ZtransBox->value();
             geom->Translate(world);
 
             // calculate rotation matrix
             double x = m_Controls->m_XrotBox->value()*M_PI/180;
             double y = m_Controls->m_YrotBox->value()*M_PI/180;
             double z = m_Controls->m_ZrotBox->value()*M_PI/180;
             itk::Matrix< double, 3, 3 > rotX; rotX.SetIdentity();
             rotX[1][1] = cos(x);
             rotX[2][2] = rotX[1][1];
             rotX[1][2] = -sin(x);
             rotX[2][1] = -rotX[1][2];
             itk::Matrix< double, 3, 3 > rotY; rotY.SetIdentity();
             rotY[0][0] = cos(y);
             rotY[2][2] = rotY[0][0];
             rotY[0][2] = sin(y);
             rotY[2][0] = -rotY[0][2];
             itk::Matrix< double, 3, 3 > rotZ; rotZ.SetIdentity();
             rotZ[0][0] = cos(z);
             rotZ[1][1] = rotZ[0][0];
             rotZ[0][1] = -sin(z);
             rotZ[1][0] = -rotZ[0][1];
             itk::Matrix< double, 3, 3 > rot = rotZ*rotY*rotX;
 
             // transform control point coordinate into geometry translation
             geom->SetOrigin(pe->GetWorldControlPoint(0));
             mitk::Point2D cp; cp.Fill(0.0);
             pe->SetControlPoint(0, cp);
 
             // rotate fiducial
             geom->GetIndexToWorldTransform()->SetMatrix(rot*geom->GetIndexToWorldTransform()->GetMatrix());
             pe->Modified();
         }
         if (m_Controls->m_RealTimeFibers->isChecked())
             GenerateFibers();
     }
     mitk::RenderingManager::GetInstance()->RequestUpdateAll();
 }
 
 void QmitkFiberfoxView::CopyBundles()
 {
     if ( m_SelectedBundles.size()<1 ){
         QMessageBox::information( NULL, "Warning", "Select at least one fiber bundle!");
         MITK_WARN("QmitkFiberFoxView") << "Select at least one fiber bundle!";
         return;
     }
 
     for (std::vector<mitk::DataNode::Pointer>::const_iterator it = m_SelectedBundles.begin(); it!=m_SelectedBundles.end(); ++it)
     {
         // find parent image
         mitk::DataNode::Pointer parentNode;
         mitk::DataStorage::SetOfObjects::ConstPointer parentImgs = GetDataStorage()->GetSources(*it);
         for( mitk::DataStorage::SetOfObjects::const_iterator it2 = parentImgs->begin(); it2 != parentImgs->end(); ++it2 )
         {
             mitk::DataNode::Pointer pImgNode = *it2;
             if ( pImgNode.IsNotNull() && dynamic_cast<mitk::Image*>(pImgNode->GetData()) )
             {
                 parentNode = pImgNode;
                 break;
             }
         }
 
         mitk::FiberBundle::Pointer fib = dynamic_cast<mitk::FiberBundle*>((*it)->GetData());
         mitk::FiberBundle::Pointer newBundle = fib->GetDeepCopy();
         QString name((*it)->GetName().c_str());
         name += "_copy";
 
         mitk::DataNode::Pointer fbNode = mitk::DataNode::New();
         fbNode->SetData(newBundle);
         fbNode->SetName(name.toStdString());
         fbNode->SetVisibility(true);
         if (parentNode.IsNotNull())
             GetDataStorage()->Add(fbNode, parentNode);
         else
             GetDataStorage()->Add(fbNode);
 
         // copy child fiducials
         if (m_Controls->m_IncludeFiducials->isChecked())
         {
             mitk::DataStorage::SetOfObjects::ConstPointer derivations = GetDataStorage()->GetDerivations(*it);
             for( mitk::DataStorage::SetOfObjects::const_iterator it2 = derivations->begin(); it2 != derivations->end(); ++it2 )
             {
                 mitk::DataNode::Pointer fiducialNode = *it2;
                 if ( fiducialNode.IsNotNull() && dynamic_cast<mitk::PlanarEllipse*>(fiducialNode->GetData()) )
                 {
                     mitk::PlanarEllipse::Pointer pe = dynamic_cast<mitk::PlanarEllipse*>(fiducialNode->GetData())->Clone();
                     mitk::DataNode::Pointer newNode = mitk::DataNode::New();
                     newNode->SetData(pe);
                     newNode->SetName(fiducialNode->GetName());
                     newNode->SetBoolProperty("planarfigure.3drendering", true);
                     GetDataStorage()->Add(newNode, fbNode);
 
                 }
             }
         }
     }
     mitk::RenderingManager::GetInstance()->RequestUpdateAll();
 }
 
 void QmitkFiberfoxView::JoinBundles()
 {
     if ( m_SelectedBundles.size()<2 ){
         QMessageBox::information( NULL, "Warning", "Select at least two fiber bundles!");
         MITK_WARN("QmitkFiberFoxView") << "Select at least two fiber bundles!";
         return;
     }
 
     std::vector<mitk::DataNode::Pointer>::const_iterator it = m_SelectedBundles.begin();
     mitk::FiberBundle::Pointer newBundle = dynamic_cast<mitk::FiberBundle*>((*it)->GetData());
     QString name("");
     name += QString((*it)->GetName().c_str());
     ++it;
     for (; it!=m_SelectedBundles.end(); ++it)
     {
         newBundle = newBundle->AddBundle(dynamic_cast<mitk::FiberBundle*>((*it)->GetData()));
         name += "+"+QString((*it)->GetName().c_str());
     }
 
     mitk::DataNode::Pointer fbNode = mitk::DataNode::New();
     fbNode->SetData(newBundle);
     fbNode->SetName(name.toStdString());
     fbNode->SetVisibility(true);
     GetDataStorage()->Add(fbNode);
     mitk::RenderingManager::GetInstance()->RequestUpdateAll();
 }
 
 void QmitkFiberfoxView::UpdateGui()
 {
     m_Controls->m_GeometryFrame->setEnabled(true);
     m_Controls->m_GeometryMessage->setVisible(false);
     m_Controls->m_DiffusionPropsMessage->setVisible(false);
     m_Controls->m_FiberGenMessage->setVisible(true);
 
     m_Controls->m_TransformBundlesButton->setEnabled(false);
     m_Controls->m_CopyBundlesButton->setEnabled(false);
     m_Controls->m_GenerateFibersButton->setEnabled(false);
     m_Controls->m_FlipButton->setEnabled(false);
     m_Controls->m_CircleButton->setEnabled(false);
     m_Controls->m_BvalueBox->setEnabled(true);
     m_Controls->m_NumGradientsBox->setEnabled(true);
     m_Controls->m_JoinBundlesButton->setEnabled(false);
     m_Controls->m_AlignOnGrid->setEnabled(false);
 
     // Fiber generation gui
     if (m_SelectedFiducial.IsNotNull())
     {
         m_Controls->m_TransformBundlesButton->setEnabled(true);
         m_Controls->m_FlipButton->setEnabled(true);
         m_Controls->m_AlignOnGrid->setEnabled(true);
     }
 
-    if (m_SelectedImage.IsNotNull() || !m_SelectedBundles.empty())
+    if (m_SelectedImageNode.IsNotNull() || !m_SelectedBundles.empty())
     {
         m_Controls->m_CircleButton->setEnabled(true);
         m_Controls->m_FiberGenMessage->setVisible(false);
     }
-    if (m_SelectedImage.IsNotNull() && !m_SelectedBundles.empty())
+    if (m_SelectedImageNode.IsNotNull() && !m_SelectedBundles.empty())
         m_Controls->m_AlignOnGrid->setEnabled(true);
 
     if (!m_SelectedBundles.empty())
     {
         m_Controls->m_TransformBundlesButton->setEnabled(true);
         m_Controls->m_CopyBundlesButton->setEnabled(true);
         m_Controls->m_GenerateFibersButton->setEnabled(true);
 
         if (m_SelectedBundles.size()>1)
             m_Controls->m_JoinBundlesButton->setEnabled(true);
     }
 
     // Signal generation gui
     if (m_Controls->m_MaskComboBox->GetSelectedNode().IsNotNull() || m_Controls->m_TemplateComboBox->GetSelectedNode().IsNotNull())
     {
         m_Controls->m_GeometryMessage->setVisible(true);
         m_Controls->m_GeometryFrame->setEnabled(false);
     }
 
     if (m_Controls->m_TemplateComboBox->GetSelectedNode().IsNotNull() && mitk::DiffusionPropertyHelper::IsDiffusionWeightedImage( dynamic_cast<mitk::Image*>(m_Controls->m_TemplateComboBox->GetSelectedNode()->GetData())))
     {
         m_Controls->m_DiffusionPropsMessage->setVisible(true);
         m_Controls->m_BvalueBox->setEnabled(false);
         m_Controls->m_NumGradientsBox->setEnabled(false);
         m_Controls->m_GeometryMessage->setVisible(true);
         m_Controls->m_GeometryFrame->setEnabled(false);
     }
 }
 
 void QmitkFiberfoxView::OnSelectionChanged( berry::IWorkbenchPart::Pointer, const QList<mitk::DataNode::Pointer>& nodes )
 {
     m_SelectedBundles2.clear();
     m_SelectedImages.clear();
     m_SelectedFiducials.clear();
     m_SelectedFiducial = NULL;
     m_SelectedBundles.clear();
-    m_SelectedImage = NULL;
+    m_SelectedImageNode = NULL;
 
     // iterate all selected objects, adjust warning visibility
     for( int i=0; i<nodes.size(); i++)
     {
         mitk::DataNode::Pointer node = nodes.at(i);
 
 //        bool isDiffusionImage(false);
 //        if ( node.IsNotNull() )
 //        {
 //          isDiffusionImage = mitk::DiffusionPropertyHelper::IsDiffusionWeightedImage( dynamic_cast<mitk::Image *>(node->GetData()));
 //        }
 
 //        if ( node.IsNotNull() && isDiffusionImage )
 //        {
 //            m_SelectedDWI = node;
 //            m_SelectedImage = node;
 //            m_SelectedImages.push_back(node);
 //        }
 
         if( node.IsNotNull() && dynamic_cast<mitk::Image*>(node->GetData()) )
         {
             m_SelectedImages.push_back(node);
-            m_SelectedImage = node;
+            m_SelectedImageNode = node;
         }
         else if ( node.IsNotNull() && dynamic_cast<mitk::FiberBundle*>(node->GetData()) )
         {
             m_SelectedBundles2.push_back(node);
             if (m_Controls->m_RealTimeFibers->isChecked())
             {
                 m_SelectedBundles.push_back(node);
                 mitk::FiberBundle::Pointer newFib = dynamic_cast<mitk::FiberBundle*>(node->GetData());
                 if (newFib->GetNumFibers()!=m_Controls->m_FiberDensityBox->value())
                     GenerateFibers();
             }
             else
                 m_SelectedBundles.push_back(node);
         }
         else if ( node.IsNotNull() && dynamic_cast<mitk::PlanarEllipse*>(node->GetData()) )
         {
             m_SelectedFiducials.push_back(node);
             m_SelectedFiducial = node;
             m_SelectedBundles.clear();
             mitk::DataStorage::SetOfObjects::ConstPointer parents = GetDataStorage()->GetSources(node);
             for( mitk::DataStorage::SetOfObjects::const_iterator it = parents->begin(); it != parents->end(); ++it )
             {
                 mitk::DataNode::Pointer pNode = *it;
                 if ( pNode.IsNotNull() && dynamic_cast<mitk::FiberBundle*>(pNode->GetData()) )
                     m_SelectedBundles.push_back(pNode);
             }
         }
     }
     UpdateGui();
 }
 
 
 void QmitkFiberfoxView::EnableCrosshairNavigation()
 {
     MITK_DEBUG << "EnableCrosshairNavigation";
 
     // enable the crosshair navigation
     if (mitk::ILinkedRenderWindowPart* linkedRenderWindow =
             dynamic_cast<mitk::ILinkedRenderWindowPart*>(this->GetRenderWindowPart()))
     {
         MITK_DEBUG << "enabling linked navigation";
         linkedRenderWindow->EnableLinkedNavigation(true);
         //        linkedRenderWindow->EnableSlicingPlanes(true);
     }
 
     if (m_Controls->m_RealTimeFibers->isChecked())
         GenerateFibers();
 }
 
 void QmitkFiberfoxView::DisableCrosshairNavigation()
 {
     MITK_DEBUG << "DisableCrosshairNavigation";
 
     // disable the crosshair navigation during the drawing
     if (mitk::ILinkedRenderWindowPart* linkedRenderWindow =
             dynamic_cast<mitk::ILinkedRenderWindowPart*>(this->GetRenderWindowPart()))
     {
         MITK_DEBUG << "disabling linked navigation";
         linkedRenderWindow->EnableLinkedNavigation(false);
         //        linkedRenderWindow->EnableSlicingPlanes(false);
     }
 }
 
 void QmitkFiberfoxView::NodeRemoved(const mitk::DataNode* node)
 {
     mitk::DataNode* nonConstNode = const_cast<mitk::DataNode*>(node);
     std::map<mitk::DataNode*, QmitkPlanarFigureData>::iterator it = m_DataNodeToPlanarFigureData.find(nonConstNode);
 
     if (dynamic_cast<FiberBundle*>(node->GetData()))
     {
         m_SelectedBundles.clear();
         m_SelectedBundles2.clear();
     }
     else if (dynamic_cast<Image*>(node->GetData()))
         m_SelectedImages.clear();
 
     if( it != m_DataNodeToPlanarFigureData.end() )
     {
         QmitkPlanarFigureData& data = it->second;
 
         // remove observers
         data.m_Figure->RemoveObserver( data.m_EndPlacementObserverTag );
         data.m_Figure->RemoveObserver( data.m_SelectObserverTag );
         data.m_Figure->RemoveObserver( data.m_StartInteractionObserverTag );
         data.m_Figure->RemoveObserver( data.m_EndInteractionObserverTag );
 
         m_DataNodeToPlanarFigureData.erase( it );
     }
 }
 
 void QmitkFiberfoxView::NodeAdded( const mitk::DataNode* node )
 {
     // add observer for selection in renderwindow
     mitk::PlanarFigure* figure = dynamic_cast<mitk::PlanarFigure*>(node->GetData());
     bool isPositionMarker (false);
     node->GetBoolProperty("isContourMarker", isPositionMarker);
     if( figure && !isPositionMarker )
     {
         MITK_DEBUG << "figure added. will add interactor if needed.";
         mitk::PlanarFigureInteractor::Pointer figureInteractor
                 = dynamic_cast<mitk::PlanarFigureInteractor*>(node->GetDataInteractor().GetPointer());
 
         mitk::DataNode* nonConstNode = const_cast<mitk::DataNode*>( node );
         if(figureInteractor.IsNull())
         {
             figureInteractor = mitk::PlanarFigureInteractor::New();
             us::Module* planarFigureModule = us::ModuleRegistry::GetModule( "MitkPlanarFigure" );
             figureInteractor->LoadStateMachine("PlanarFigureInteraction.xml", planarFigureModule );
             figureInteractor->SetEventConfig( "PlanarFigureConfig.xml", planarFigureModule );
             figureInteractor->SetDataNode( nonConstNode );
         }
 
         MITK_DEBUG << "will now add observers for planarfigure";
         QmitkPlanarFigureData data;
         data.m_Figure = figure;
 
         //        // add observer for event when figure has been placed
         typedef itk::SimpleMemberCommand< QmitkFiberfoxView > SimpleCommandType;
         //        SimpleCommandType::Pointer initializationCommand = SimpleCommandType::New();
         //        initializationCommand->SetCallbackFunction( this, &QmitkFiberfoxView::PlanarFigureInitialized );
         //        data.m_EndPlacementObserverTag = figure->AddObserver( mitk::EndPlacementPlanarFigureEvent(), initializationCommand );
 
         // add observer for event when figure is picked (selected)
         typedef itk::MemberCommand< QmitkFiberfoxView > MemberCommandType;
         MemberCommandType::Pointer selectCommand = MemberCommandType::New();
         selectCommand->SetCallbackFunction( this, &QmitkFiberfoxView::PlanarFigureSelected );
         data.m_SelectObserverTag = figure->AddObserver( mitk::SelectPlanarFigureEvent(), selectCommand );
 
         // add observer for event when interaction with figure starts
         SimpleCommandType::Pointer startInteractionCommand = SimpleCommandType::New();
         startInteractionCommand->SetCallbackFunction( this, &QmitkFiberfoxView::DisableCrosshairNavigation);
         data.m_StartInteractionObserverTag = figure->AddObserver( mitk::StartInteractionPlanarFigureEvent(), startInteractionCommand );
 
         // add observer for event when interaction with figure starts
         SimpleCommandType::Pointer endInteractionCommand = SimpleCommandType::New();
         endInteractionCommand->SetCallbackFunction( this, &QmitkFiberfoxView::EnableCrosshairNavigation);
         data.m_EndInteractionObserverTag = figure->AddObserver( mitk::EndInteractionPlanarFigureEvent(), endInteractionCommand );
 
         m_DataNodeToPlanarFigureData[nonConstNode] = data;
     }
 }
 
 void QmitkFiberfoxView::PlanarFigureSelected( itk::Object* object, const itk::EventObject& )
 {
     mitk::TNodePredicateDataType<mitk::PlanarFigure>::Pointer isPf = mitk::TNodePredicateDataType<mitk::PlanarFigure>::New();
 
     mitk::DataStorage::SetOfObjects::ConstPointer allPfs = this->GetDataStorage()->GetSubset( isPf );
     for ( mitk::DataStorage::SetOfObjects::const_iterator it = allPfs->begin(); it!=allPfs->end(); ++it)
     {
         mitk::DataNode* node = *it;
 
         if( node->GetData() == object )
         {
             node->SetSelected(true);
             m_SelectedFiducial = node;
         }
         else
             node->SetSelected(false);
     }
     UpdateGui();
     this->RequestRenderWindowUpdate();
 }
 
 void QmitkFiberfoxView::SetFocus()
 {
     m_Controls->m_CircleButton->setFocus();
 }
 
 
 void QmitkFiberfoxView::SetOutputPath()
 {
     // SELECT FOLDER DIALOG
 
     string outputPath = QFileDialog::getExistingDirectory(NULL, "Save images to...", QString(outputPath.c_str())).toStdString();
 
     if (outputPath.empty())
         m_Controls->m_SavePathEdit->setText("-");
     else
     {
         outputPath += "/";
         m_Controls->m_SavePathEdit->setText(QString(outputPath.c_str()));
     }
 }
diff --git a/Plugins/org.mitk.gui.qt.diffusionimaging/src/internal/QmitkFiberfoxView.h b/Plugins/org.mitk.gui.qt.diffusionimaging/src/internal/QmitkFiberfoxView.h
index 3d261cdab2..75f7990c86 100755
--- a/Plugins/org.mitk.gui.qt.diffusionimaging/src/internal/QmitkFiberfoxView.h
+++ b/Plugins/org.mitk.gui.qt.diffusionimaging/src/internal/QmitkFiberfoxView.h
@@ -1,218 +1,219 @@
 /*===================================================================
 
 The Medical Imaging Interaction Toolkit (MITK)
 
 Copyright (c) German Cancer Research Center,
 Division of Medical and Biological Informatics.
 All rights reserved.
 
 This software is distributed WITHOUT ANY WARRANTY; without
 even the implied warranty of MERCHANTABILITY or FITNESS FOR
 A PARTICULAR PURPOSE.
 
 See LICENSE.txt or http://www.mitk.org for details.
 
 ===================================================================*/
 
 
 
 #include <berryISelectionListener.h>
 #include <berryIStructuredSelection.h>
 
 #include <QmitkAbstractView.h>
 #include "ui_QmitkFiberfoxViewControls.h"
 #include <itkVectorImage.h>
 #include <itkVectorContainer.h>
 #include <itkOrientationDistributionFunction.h>
 
 #ifndef Q_MOC_RUN
 #include <mitkFiberBundle.h>
 #include <mitkPlanarEllipse.h>
 #include <mitkDiffusionNoiseModel.h>
 #include <mitkDiffusionSignalModel.h>
 #include <mitkRicianNoiseModel.h>
 #include <itkTractsToDWIImageFilter.h>
 #include <itkAddArtifactsToDwiImageFilter.h>
 #include <mitkTensorModel.h>
 #include <mitkBallModel.h>
 #include <mitkStickModel.h>
 #include <mitkAstroStickModel.h>
 #include <mitkDotModel.h>
 #include <mitkFiberfoxParameters.h>
 #include <itkStatisticsImageFilter.h>
 #include <mitkDiffusionPropertyHelper.h>
 #endif
 
 #include <QThread>
 #include <QObject>
 #include <QTimer>
 #include <QTime>
 
 /*!
 \brief View for fiber based diffusion software phantoms (Fiberfox). See "Fiberfox: Facilitating the creation of realistic white matter software phantoms" (DOI: 10.1002/mrm.25045) for details.
 \sa QmitkFunctionality
 \ingroup Functionalities
 */
 
 // Forward Qt class declarations
 
 using namespace std;
 
 class QmitkFiberfoxView;
 
 class QmitkFiberfoxWorker : public QObject
 {
     Q_OBJECT
 
 public:
 
     QmitkFiberfoxWorker(QmitkFiberfoxView* view);
     int m_FilterType;
 
 public slots:
 
     void run();
 
 private:
 
     QmitkFiberfoxView*                  m_View;
 };
 
 class QmitkFiberfoxView : public QmitkAbstractView
 {
 
     // this is needed for all Qt objects that should have a Qt meta-object
     // (everything that derives from QObject and wants to have signal/slots)
     Q_OBJECT
 
 public:
 
     static const string VIEW_ID;
 
     QmitkFiberfoxView();
     virtual ~QmitkFiberfoxView();
 
     virtual void CreateQtPartControl(QWidget *parent);
     void SetFocus();
 
     typedef mitk::DiffusionPropertyHelper::GradientDirectionType            GradientDirectionType;
     typedef mitk::DiffusionPropertyHelper::GradientDirectionsContainerType  GradientDirectionContainerType;
     typedef itk::Vector<double,3>           GradientType;
     typedef vector<GradientType>            GradientListType;
-    typedef itk::VectorImage< short, 3 >                                    ItkDwiType;
+    typedef itk::VectorImage< short, 3 >    ItkDwiType;
     typedef itk::Image<double, 3>           ItkDoubleImgType;
+    typedef itk::Image<float, 3>            ItkFloatImgType;
     typedef itk::Image<unsigned char, 3>    ItkUcharImgType;
 
     template<int ndirs> vector<itk::Vector<double,3> > MakeGradientList();
 
 protected slots:
 
     void SetOutputPath();           ///< path where image is automatically saved to after the simulation is finished
     void LoadParameters();          ///< load fiberfox parameters
     void SaveParameters();          ///< save fiberfox parameters
 
     void BeforeThread();
     void AfterThread();
     void KillThread();              ///< abort simulation
     void UpdateSimulationStatus();  ///< print simulation progress and satus messages
 
     void OnDrawROI();               ///< adds new ROI, handles interactors etc.
     void OnAddBundle();             ///< adds new fiber bundle to datastorage
     void OnFlipButton();            ///< negate one coordinate of the fiber waypoints in the selcted planar figure. needed in case of unresolvable twists
     void GenerateFibers();          ///< generate fibers from the selected ROIs
     void GenerateImage();           ///< start image simulation
     void JoinBundles();             ///< merges selcted fiber bundles into one
     void CopyBundles();             ///< add copy of the selected bundle to the datamanager
     void ApplyTransform();          ///< rotate and shift selected bundles
     void AlignOnGrid();             ///< shift selected fiducials to nearest voxel center
     void Comp1ModelFrameVisibility(int index);  ///< only show parameters of selected signal model for compartment 1
     void Comp2ModelFrameVisibility(int index);  ///< only show parameters of selected signal model for compartment 2
     void Comp3ModelFrameVisibility(int index);  ///< only show parameters of selected signal model for compartment 3
     void Comp4ModelFrameVisibility(int index);  ///< only show parameters of selected signal model for compartment 4
     void ShowAdvancedOptions(int state);
 
     /** update fibers if any parameter changes */
     void OnFiberDensityChanged(int value);
     void OnFiberSamplingChanged(double value);
     void OnTensionChanged(double value);
     void OnContinuityChanged(double value);
     void OnBiasChanged(double value);
     void OnVarianceChanged(double value);
     void OnDistributionChanged(int value);
     void OnConstantRadius(int value);
 
     /** update GUI elements */
     void OnAddNoise(int value);
     void OnAddGhosts(int value);
     void OnAddDistortions(int value);
     void OnAddEddy(int value);
     void OnAddSpikes(int value);
     void OnAddAliasing(int value);
     void OnAddMotion(int value);
     void OnMaskSelected(int value);
     void OnFibSelected(int value);
     void OnTemplateSelected(int value);
 
 protected:
 
     /// \brief called by QmitkFunctionality when DataManager's selection has changed
     virtual void OnSelectionChanged(berry::IWorkbenchPart::Pointer, const QList<mitk::DataNode::Pointer>&);
 
     GradientListType GenerateHalfShell(int NPoints);    ///< generate vectors distributed over the halfsphere
 
     Ui::QmitkFiberfoxViewControls* m_Controls;
 
     void SimulateForExistingDwi(mitk::DataNode* imageNode);     ///< add artifacts to existing diffusion weighted image
     void SimulateImageFromFibers(mitk::DataNode* fiberNode);    ///< simulate new diffusion weighted image
     template< class ScalarType > FiberfoxParameters< ScalarType > UpdateImageParameters();  ///< update fiberfox paramater object (template parameter defines noise model type)
     void UpdateGui();                                           ///< enable/disbale buttons etc. according to current datamanager selection
     void PlanarFigureSelected( itk::Object* object, const itk::EventObject& );
     void EnableCrosshairNavigation();               ///< enable crosshair navigation if planar figure interaction ends
     void DisableCrosshairNavigation();              ///< disable crosshair navigation if planar figure interaction starts
     void NodeAdded( const mitk::DataNode* node );   ///< add observers
     void NodeRemoved(const mitk::DataNode* node);   ///< remove observers
 
     /** structure to keep track of planar figures and observers */
     struct QmitkPlanarFigureData
     {
         QmitkPlanarFigureData()
             : m_Figure(0)
             , m_EndPlacementObserverTag(0)
             , m_SelectObserverTag(0)
             , m_StartInteractionObserverTag(0)
             , m_EndInteractionObserverTag(0)
             , m_Flipped(0)
         {
         }
         mitk::PlanarFigure* m_Figure;
         unsigned int m_EndPlacementObserverTag;
         unsigned int m_SelectObserverTag;
         unsigned int m_StartInteractionObserverTag;
         unsigned int m_EndInteractionObserverTag;
         unsigned int m_Flipped;
     };
 
     std::map<mitk::DataNode*, QmitkPlanarFigureData>    m_DataNodeToPlanarFigureData;   ///< map each planar figure uniquely to a QmitkPlanarFigureData
     mitk::DataNode::Pointer                             m_SelectedFiducial;             ///< selected planar ellipse
-    mitk::DataNode::Pointer                             m_SelectedImage;
+    mitk::DataNode::Pointer                             m_SelectedImageNode;
     vector< mitk::DataNode::Pointer >                   m_SelectedBundles;
     vector< mitk::DataNode::Pointer >                   m_SelectedBundles2;
     vector< mitk::DataNode::Pointer >                   m_SelectedFiducials;
     vector< mitk::DataNode::Pointer >                   m_SelectedImages;
 
     QString m_ParameterFile;    ///< parameter file name
 
     // GUI thread
     QmitkFiberfoxWorker     m_Worker;   ///< runs filter
     QThread                 m_Thread;   ///< worker thread
     bool                    m_ThreadIsRunning;
     QTimer*                 m_SimulationTimer;
     QTime                   m_SimulationTime;
     QString                 m_SimulationStatusText;
 
     /** Image filters that do all the simulations. */
     itk::TractsToDWIImageFilter< short >::Pointer           m_TractsToDwiFilter;
     itk::AddArtifactsToDwiImageFilter< short >::Pointer     m_ArtifactsToDwiFilter;
 
     friend class QmitkFiberfoxWorker;
 };
diff --git a/Plugins/org.mitk.gui.qt.diffusionimaging/src/internal/QmitkFiberfoxViewControls.ui b/Plugins/org.mitk.gui.qt.diffusionimaging/src/internal/QmitkFiberfoxViewControls.ui
index 160817ca4d..8a1452baff 100755
--- a/Plugins/org.mitk.gui.qt.diffusionimaging/src/internal/QmitkFiberfoxViewControls.ui
+++ b/Plugins/org.mitk.gui.qt.diffusionimaging/src/internal/QmitkFiberfoxViewControls.ui
@@ -1,3108 +1,3135 @@
 <?xml version="1.0" encoding="UTF-8"?>
 <ui version="4.0">
  <class>QmitkFiberfoxViewControls</class>
  <widget class="QWidget" name="QmitkFiberfoxViewControls">
   <property name="geometry">
    <rect>
     <x>0</x>
     <y>0</y>
     <width>479</width>
     <height>2397</height>
    </rect>
   </property>
   <property name="windowTitle">
    <string>Form</string>
   </property>
   <layout class="QGridLayout" name="gridLayout_2">
    <item row="3" column="0">
     <widget class="QCommandLinkButton" name="m_LoadParametersButton">
      <property name="text">
       <string>Load Parameters</string>
      </property>
      <property name="icon">
       <iconset resource="../../resources/QmitkDiffusionImaging.qrc">
        <normaloff>:/QmitkDiffusionImaging/general_icons/upload.ico</normaloff>:/QmitkDiffusionImaging/general_icons/upload.ico</iconset>
      </property>
     </widget>
    </item>
    <item row="1" column="0">
     <widget class="QTabWidget" name="tabWidget">
      <property name="currentIndex">
       <number>0</number>
      </property>
      <widget class="QWidget" name="tab">
       <attribute name="title">
        <string>Fiber Definition</string>
       </attribute>
       <layout class="QGridLayout" name="gridLayout_8">
        <item row="7" column="0">
         <spacer name="verticalSpacer">
          <property name="orientation">
           <enum>Qt::Vertical</enum>
          </property>
          <property name="sizeHint" stdset="0">
           <size>
            <width>20</width>
            <height>40</height>
           </size>
          </property>
         </spacer>
        </item>
        <item row="0" column="0">
         <widget class="QLabel" name="m_FiberGenMessage">
          <property name="styleSheet">
           <string notr="true">color: rgb(255, 0, 0);</string>
          </property>
          <property name="text">
           <string>Please select an image or an existing fiber bundle to draw the fiber fiducials. If you can't provide a suitable image, generate one using the &quot;Signal Generation&quot; tab.</string>
          </property>
          <property name="textFormat">
           <enum>Qt::AutoText</enum>
          </property>
          <property name="alignment">
           <set>Qt::AlignJustify|Qt::AlignVCenter</set>
          </property>
          <property name="wordWrap">
           <bool>true</bool>
          </property>
         </widget>
        </item>
        <item row="5" column="0">
         <widget class="QGroupBox" name="groupBox_7">
          <property name="title">
           <string>Fiducial Options</string>
          </property>
          <layout class="QGridLayout" name="gridLayout_16">
           <item row="0" column="0">
            <widget class="QCheckBox" name="m_ConstantRadiusBox">
             <property name="toolTip">
              <string>All fiducials are treated as circles with the same radius as the first fiducial. </string>
             </property>
             <property name="text">
              <string>Use Constant Fiducial Radius</string>
             </property>
             <property name="checked">
              <bool>false</bool>
             </property>
            </widget>
           </item>
           <item row="1" column="0">
            <widget class="QCommandLinkButton" name="m_AlignOnGrid">
             <property name="enabled">
              <bool>false</bool>
             </property>
             <property name="toolTip">
              <string>Align selected fiducials with voxel grid. Shifts selected fiducials to nearest voxel center.</string>
             </property>
             <property name="text">
              <string>Align With Grid</string>
             </property>
             <property name="icon">
              <iconset resource="../../resources/QmitkDiffusionImaging.qrc">
               <normaloff>:/QmitkDiffusionImaging/general_icons/right.ico</normaloff>:/QmitkDiffusionImaging/general_icons/right.ico</iconset>
             </property>
            </widget>
           </item>
          </layout>
         </widget>
        </item>
        <item row="6" column="0" colspan="2">
         <widget class="QGroupBox" name="groupBox_4">
          <property name="title">
           <string>Operations</string>
          </property>
          <layout class="QGridLayout" name="gridLayout_11">
           <item row="5" column="0">
            <widget class="QCommandLinkButton" name="m_JoinBundlesButton">
             <property name="enabled">
              <bool>false</bool>
             </property>
             <property name="text">
              <string>Join Bundles</string>
             </property>
             <property name="icon">
              <iconset resource="../../resources/QmitkDiffusionImaging.qrc">
               <normaloff>:/QmitkDiffusionImaging/general_icons/plus.ico</normaloff>:/QmitkDiffusionImaging/general_icons/plus.ico</iconset>
             </property>
            </widget>
           </item>
           <item row="2" column="0">
            <widget class="QFrame" name="frame_4">
             <property name="frameShape">
              <enum>QFrame::NoFrame</enum>
             </property>
             <property name="frameShadow">
              <enum>QFrame::Raised</enum>
             </property>
             <layout class="QGridLayout" name="gridLayout_12">
              <property name="leftMargin">
               <number>0</number>
              </property>
              <property name="topMargin">
               <number>0</number>
              </property>
              <property name="rightMargin">
               <number>0</number>
              </property>
              <property name="bottomMargin">
               <number>0</number>
              </property>
              <item row="1" column="2">
               <widget class="QLabel" name="m_TensorsToDWIBValueLabel_18">
                <property name="toolTip">
                 <string/>
                </property>
                <property name="statusTip">
                 <string/>
                </property>
                <property name="whatsThis">
                 <string/>
                </property>
                <property name="text">
                 <string>Y</string>
                </property>
                <property name="wordWrap">
                 <bool>false</bool>
                </property>
               </widget>
              </item>
              <item row="2" column="1">
               <widget class="QDoubleSpinBox" name="m_XrotBox">
                <property name="toolTip">
                 <string>Rotation angle (in degree) around x-axis.</string>
                </property>
+               <property name="decimals">
+                <number>3</number>
+               </property>
                <property name="minimum">
                 <double>-360.000000000000000</double>
                </property>
                <property name="maximum">
                 <double>360.000000000000000</double>
                </property>
                <property name="singleStep">
                 <double>0.100000000000000</double>
                </property>
               </widget>
              </item>
              <item row="1" column="0">
               <widget class="QLabel" name="m_TensorsToDWIBValueLabel_22">
                <property name="toolTip">
                 <string/>
                </property>
                <property name="statusTip">
                 <string/>
                </property>
                <property name="whatsThis">
                 <string/>
                </property>
                <property name="text">
                 <string>Axis:</string>
                </property>
                <property name="wordWrap">
                 <bool>false</bool>
                </property>
               </widget>
              </item>
              <item row="2" column="2">
               <widget class="QDoubleSpinBox" name="m_YrotBox">
                <property name="toolTip">
                 <string>Rotation angle (in degree) around y-axis.</string>
                </property>
+               <property name="decimals">
+                <number>3</number>
+               </property>
                <property name="minimum">
                 <double>-360.000000000000000</double>
                </property>
                <property name="maximum">
                 <double>360.000000000000000</double>
                </property>
                <property name="singleStep">
                 <double>0.100000000000000</double>
                </property>
               </widget>
              </item>
              <item row="3" column="0">
               <widget class="QLabel" name="m_TensorsToDWIBValueLabel_21">
                <property name="toolTip">
                 <string/>
                </property>
                <property name="statusTip">
                 <string/>
                </property>
                <property name="whatsThis">
                 <string/>
                </property>
                <property name="text">
                 <string>Translation:</string>
                </property>
                <property name="wordWrap">
                 <bool>false</bool>
                </property>
               </widget>
              </item>
              <item row="3" column="3">
               <widget class="QDoubleSpinBox" name="m_ZtransBox">
                <property name="toolTip">
                 <string>Translation (in mm) in direction of the z-axis.</string>
                </property>
+               <property name="decimals">
+                <number>3</number>
+               </property>
                <property name="minimum">
                 <double>-1000.000000000000000</double>
                </property>
                <property name="maximum">
                 <double>1000.000000000000000</double>
                </property>
                <property name="singleStep">
                 <double>0.100000000000000</double>
                </property>
               </widget>
              </item>
              <item row="3" column="2">
               <widget class="QDoubleSpinBox" name="m_YtransBox">
                <property name="toolTip">
                 <string>Translation (in mm) in direction of the y-axis.</string>
                </property>
+               <property name="decimals">
+                <number>3</number>
+               </property>
                <property name="minimum">
                 <double>-1000.000000000000000</double>
                </property>
                <property name="maximum">
                 <double>1000.000000000000000</double>
                </property>
                <property name="singleStep">
                 <double>0.100000000000000</double>
                </property>
               </widget>
              </item>
              <item row="1" column="1">
               <widget class="QLabel" name="m_TensorsToDWIBValueLabel_17">
                <property name="toolTip">
                 <string/>
                </property>
                <property name="statusTip">
                 <string/>
                </property>
                <property name="whatsThis">
                 <string/>
                </property>
                <property name="text">
                 <string>X</string>
                </property>
                <property name="wordWrap">
                 <bool>false</bool>
                </property>
               </widget>
              </item>
              <item row="2" column="0">
               <widget class="QLabel" name="m_TensorsToDWIBValueLabel_20">
                <property name="toolTip">
                 <string/>
                </property>
                <property name="statusTip">
                 <string/>
                </property>
                <property name="whatsThis">
                 <string/>
                </property>
                <property name="text">
                 <string>Rotation:</string>
                </property>
                <property name="wordWrap">
                 <bool>false</bool>
                </property>
               </widget>
              </item>
              <item row="1" column="3">
               <widget class="QLabel" name="m_TensorsToDWIBValueLabel_19">
                <property name="toolTip">
                 <string/>
                </property>
                <property name="statusTip">
                 <string/>
                </property>
                <property name="whatsThis">
                 <string/>
                </property>
                <property name="text">
                 <string>Z</string>
                </property>
                <property name="wordWrap">
                 <bool>false</bool>
                </property>
               </widget>
              </item>
              <item row="2" column="3">
               <widget class="QDoubleSpinBox" name="m_ZrotBox">
                <property name="toolTip">
                 <string>Rotation angle (in degree) around z-axis.</string>
                </property>
+               <property name="decimals">
+                <number>3</number>
+               </property>
                <property name="minimum">
                 <double>-360.000000000000000</double>
                </property>
                <property name="maximum">
                 <double>360.000000000000000</double>
                </property>
                <property name="singleStep">
                 <double>0.100000000000000</double>
                </property>
               </widget>
              </item>
              <item row="3" column="1">
               <widget class="QDoubleSpinBox" name="m_XtransBox">
                <property name="toolTip">
                 <string>Translation (in mm) in direction of the x-axis.</string>
                </property>
+               <property name="decimals">
+                <number>3</number>
+               </property>
                <property name="minimum">
                 <double>-1000.000000000000000</double>
                </property>
                <property name="maximum">
                 <double>1000.000000000000000</double>
                </property>
                <property name="singleStep">
                 <double>0.100000000000000</double>
                </property>
               </widget>
              </item>
              <item row="4" column="0">
               <widget class="QLabel" name="m_TensorsToDWIBValueLabel_24">
                <property name="toolTip">
                 <string/>
                </property>
                <property name="statusTip">
                 <string/>
                </property>
                <property name="whatsThis">
                 <string/>
                </property>
                <property name="text">
                 <string>Scaling:</string>
                </property>
                <property name="wordWrap">
                 <bool>false</bool>
                </property>
               </widget>
              </item>
              <item row="4" column="1">
               <widget class="QDoubleSpinBox" name="m_XscaleBox">
                <property name="toolTip">
                 <string>Scaling factor for selected fiber bundle along the x-axis.</string>
                </property>
                <property name="minimum">
                 <double>0.010000000000000</double>
                </property>
                <property name="maximum">
                 <double>10.000000000000000</double>
                </property>
                <property name="singleStep">
                 <double>0.010000000000000</double>
                </property>
                <property name="value">
                 <double>1.000000000000000</double>
                </property>
               </widget>
              </item>
              <item row="4" column="2">
               <widget class="QDoubleSpinBox" name="m_YscaleBox">
                <property name="toolTip">
                 <string>Scaling factor for selected fiber bundle along the y-axis.</string>
                </property>
                <property name="minimum">
                 <double>0.010000000000000</double>
                </property>
                <property name="maximum">
                 <double>10.000000000000000</double>
                </property>
                <property name="singleStep">
                 <double>0.010000000000000</double>
                </property>
                <property name="value">
                 <double>1.000000000000000</double>
                </property>
               </widget>
              </item>
              <item row="4" column="3">
               <widget class="QDoubleSpinBox" name="m_ZscaleBox">
                <property name="toolTip">
                 <string>Scaling factor for selected fiber bundle along the z-axis.</string>
                </property>
                <property name="minimum">
                 <double>0.010000000000000</double>
                </property>
                <property name="maximum">
                 <double>10.000000000000000</double>
                </property>
                <property name="singleStep">
                 <double>0.010000000000000</double>
                </property>
                <property name="value">
                 <double>1.000000000000000</double>
                </property>
               </widget>
              </item>
             </layout>
            </widget>
           </item>
           <item row="4" column="0">
            <widget class="QCommandLinkButton" name="m_CopyBundlesButton">
             <property name="enabled">
              <bool>false</bool>
             </property>
             <property name="text">
              <string>Copy Bundles</string>
             </property>
             <property name="icon">
              <iconset resource="../../resources/QmitkDiffusionImaging.qrc">
               <normaloff>:/QmitkDiffusionImaging/general_icons/copy2.ico</normaloff>:/QmitkDiffusionImaging/general_icons/copy2.ico</iconset>
             </property>
            </widget>
           </item>
           <item row="3" column="0">
            <widget class="QCommandLinkButton" name="m_TransformBundlesButton">
             <property name="enabled">
              <bool>false</bool>
             </property>
             <property name="text">
              <string>Transform Selection</string>
             </property>
             <property name="icon">
              <iconset resource="../../resources/QmitkDiffusionImaging.qrc">
               <normaloff>:/QmitkDiffusionImaging/general_icons/refresh.ico</normaloff>:/QmitkDiffusionImaging/general_icons/refresh.ico</iconset>
             </property>
            </widget>
           </item>
           <item row="6" column="0">
            <widget class="QCheckBox" name="m_IncludeFiducials">
             <property name="toolTip">
              <string>If checked, the fiducials belonging to the modified bundle are also modified.</string>
             </property>
             <property name="text">
              <string>Include Fiducials</string>
             </property>
             <property name="checked">
              <bool>true</bool>
             </property>
            </widget>
           </item>
          </layout>
         </widget>
        </item>
        <item row="4" column="0">
         <widget class="QGroupBox" name="groupBox_8">
          <property name="title">
           <string>Fiber Options</string>
          </property>
          <layout class="QGridLayout" name="gridLayout_15">
           <item row="2" column="0">
            <widget class="QFrame" name="frame_5">
             <property name="frameShape">
              <enum>QFrame::NoFrame</enum>
             </property>
             <property name="frameShadow">
              <enum>QFrame::Raised</enum>
             </property>
             <layout class="QGridLayout" name="gridLayout_9">
              <property name="leftMargin">
               <number>0</number>
              </property>
              <property name="topMargin">
               <number>0</number>
              </property>
              <property name="rightMargin">
               <number>0</number>
              </property>
              <property name="bottomMargin">
               <number>0</number>
              </property>
              <item row="2" column="0">
               <widget class="QFrame" name="m_AdvancedFiberOptionsFrame">
                <property name="frameShape">
                 <enum>QFrame::NoFrame</enum>
                </property>
                <property name="frameShadow">
                 <enum>QFrame::Raised</enum>
                </property>
                <layout class="QGridLayout" name="gridLayout_21">
                 <property name="leftMargin">
                  <number>0</number>
                 </property>
                 <property name="topMargin">
                  <number>0</number>
                 </property>
                 <property name="rightMargin">
                  <number>0</number>
                 </property>
                 <property name="bottomMargin">
                  <number>0</number>
                 </property>
                 <item row="1" column="0">
                  <widget class="QLabel" name="m_TensorsToDWIBValueLabel_5">
                   <property name="toolTip">
                    <string/>
                   </property>
                   <property name="statusTip">
                    <string/>
                   </property>
                   <property name="whatsThis">
                    <string/>
                   </property>
                   <property name="text">
                    <string>Tension:</string>
                   </property>
                   <property name="wordWrap">
                    <bool>false</bool>
                   </property>
                  </widget>
                 </item>
                 <item row="0" column="0">
                  <widget class="QLabel" name="m_TensorsToDWIBValueLabel_8">
                   <property name="toolTip">
                    <string/>
                   </property>
                   <property name="statusTip">
                    <string/>
                   </property>
                   <property name="whatsThis">
                    <string/>
                   </property>
                   <property name="text">
                    <string>Fiber Sampling:</string>
                   </property>
                   <property name="wordWrap">
                    <bool>false</bool>
                   </property>
                  </widget>
                 </item>
                 <item row="1" column="1">
                  <widget class="QDoubleSpinBox" name="m_TensionBox">
                   <property name="toolTip">
                    <string/>
                   </property>
                   <property name="decimals">
                    <number>3</number>
                   </property>
                   <property name="minimum">
                    <double>-1.000000000000000</double>
                   </property>
                   <property name="maximum">
                    <double>1.000000000000000</double>
                   </property>
                   <property name="singleStep">
                    <double>0.100000000000000</double>
                   </property>
                   <property name="value">
                    <double>0.000000000000000</double>
                   </property>
                  </widget>
                 </item>
                 <item row="3" column="1">
                  <widget class="QDoubleSpinBox" name="m_BiasBox">
                   <property name="decimals">
                    <number>3</number>
                   </property>
                   <property name="minimum">
                    <double>-1.000000000000000</double>
                   </property>
                   <property name="maximum">
                    <double>1.000000000000000</double>
                   </property>
                   <property name="singleStep">
                    <double>0.100000000000000</double>
                   </property>
                   <property name="value">
                    <double>0.000000000000000</double>
                   </property>
                  </widget>
                 </item>
                 <item row="3" column="0">
                  <widget class="QLabel" name="m_TensorsToDWIBValueLabel_7">
                   <property name="toolTip">
                    <string/>
                   </property>
                   <property name="statusTip">
                    <string/>
                   </property>
                   <property name="whatsThis">
                    <string/>
                   </property>
                   <property name="text">
                    <string>Bias:</string>
                   </property>
                   <property name="wordWrap">
                    <bool>false</bool>
                   </property>
                  </widget>
                 </item>
                 <item row="2" column="0">
                  <widget class="QLabel" name="m_TensorsToDWIBValueLabel_6">
                   <property name="toolTip">
                    <string/>
                   </property>
                   <property name="statusTip">
                    <string/>
                   </property>
                   <property name="whatsThis">
                    <string/>
                   </property>
                   <property name="text">
                    <string>Continuity:</string>
                   </property>
                   <property name="wordWrap">
                    <bool>false</bool>
                   </property>
                  </widget>
                 </item>
                 <item row="2" column="1">
                  <widget class="QDoubleSpinBox" name="m_ContinuityBox">
                   <property name="decimals">
                    <number>3</number>
                   </property>
                   <property name="minimum">
                    <double>-1.000000000000000</double>
                   </property>
                   <property name="maximum">
                    <double>1.000000000000000</double>
                   </property>
                   <property name="singleStep">
                    <double>0.100000000000000</double>
                   </property>
                   <property name="value">
                    <double>0.000000000000000</double>
                   </property>
                  </widget>
                 </item>
                 <item row="0" column="1">
                  <widget class="QDoubleSpinBox" name="m_FiberSamplingBox">
                   <property name="toolTip">
                    <string>Distance of fiber sampling points (in mm)</string>
                   </property>
                   <property name="decimals">
                    <number>1</number>
                   </property>
                   <property name="minimum">
                    <double>0.100000000000000</double>
                   </property>
                   <property name="singleStep">
                    <double>0.100000000000000</double>
                   </property>
                   <property name="value">
                    <double>1.000000000000000</double>
                   </property>
                  </widget>
                 </item>
                </layout>
               </widget>
              </item>
              <item row="1" column="0">
               <widget class="QFrame" name="frame_2">
                <property name="frameShape">
                 <enum>QFrame::NoFrame</enum>
                </property>
                <property name="frameShadow">
                 <enum>QFrame::Raised</enum>
                </property>
                <layout class="QGridLayout" name="gridLayout_25">
                 <property name="leftMargin">
                  <number>0</number>
                 </property>
                 <property name="topMargin">
                  <number>0</number>
                 </property>
                 <property name="rightMargin">
                  <number>0</number>
                 </property>
                 <property name="bottomMargin">
                  <number>0</number>
                 </property>
                 <property name="verticalSpacing">
                  <number>6</number>
                 </property>
                 <item row="0" column="0">
                  <widget class="QLabel" name="m_TensorsToDWIBValueLabel_4">
                   <property name="toolTip">
                    <string/>
                   </property>
                   <property name="statusTip">
                    <string/>
                   </property>
                   <property name="whatsThis">
                    <string/>
                   </property>
                   <property name="text">
                    <string>#Fibers:</string>
                   </property>
                   <property name="wordWrap">
                    <bool>false</bool>
                   </property>
                  </widget>
                 </item>
                 <item row="0" column="1">
                  <widget class="QSpinBox" name="m_FiberDensityBox">
                   <property name="toolTip">
                    <string>Specify number of fibers to generate for the selected bundle.</string>
                   </property>
                   <property name="minimum">
                    <number>1</number>
                   </property>
                   <property name="maximum">
                    <number>1000000</number>
                   </property>
                   <property name="singleStep">
                    <number>100</number>
                   </property>
                   <property name="value">
                    <number>100</number>
                   </property>
                  </widget>
                 </item>
                </layout>
               </widget>
              </item>
             </layout>
            </widget>
           </item>
           <item row="3" column="0">
            <widget class="QCommandLinkButton" name="m_GenerateFibersButton">
             <property name="enabled">
              <bool>false</bool>
             </property>
             <property name="text">
              <string>Generate Fibers</string>
             </property>
             <property name="icon">
              <iconset resource="../../resources/QmitkDiffusionImaging.qrc">
               <normaloff>:/QmitkDiffusionImaging/general_icons/right.ico</normaloff>:/QmitkDiffusionImaging/general_icons/right.ico</iconset>
             </property>
            </widget>
           </item>
           <item row="1" column="0">
            <widget class="QFrame" name="frame_3">
             <property name="frameShape">
              <enum>QFrame::NoFrame</enum>
             </property>
             <property name="frameShadow">
              <enum>QFrame::Raised</enum>
             </property>
             <layout class="QGridLayout" name="gridLayout_5">
              <property name="leftMargin">
               <number>0</number>
              </property>
              <property name="topMargin">
               <number>0</number>
              </property>
              <property name="rightMargin">
               <number>0</number>
              </property>
              <property name="bottomMargin">
               <number>0</number>
              </property>
              <item row="0" column="1">
               <widget class="QComboBox" name="m_DistributionBox">
                <property name="toolTip">
                 <string>Select fiber distribution inside of the fiducials.</string>
                </property>
                <item>
                 <property name="text">
                  <string>Uniform</string>
                 </property>
                </item>
                <item>
                 <property name="text">
                  <string>Gaussian</string>
                 </property>
                </item>
               </widget>
              </item>
              <item row="0" column="0">
               <widget class="QLabel" name="m_TensorsToDWIBValueLabel_9">
                <property name="toolTip">
                 <string/>
                </property>
                <property name="statusTip">
                 <string/>
                </property>
                <property name="whatsThis">
                 <string/>
                </property>
                <property name="text">
                 <string>Fiber Distribution:</string>
                </property>
                <property name="wordWrap">
                 <bool>false</bool>
                </property>
               </widget>
              </item>
              <item row="0" column="2">
               <widget class="QDoubleSpinBox" name="m_VarianceBox">
                <property name="toolTip">
                 <string>Variance of the gaussian</string>
                </property>
                <property name="decimals">
                 <number>3</number>
                </property>
                <property name="minimum">
                 <double>0.001000000000000</double>
                </property>
                <property name="maximum">
                 <double>10.000000000000000</double>
                </property>
                <property name="singleStep">
                 <double>0.010000000000000</double>
                </property>
                <property name="value">
                 <double>0.100000000000000</double>
                </property>
               </widget>
              </item>
             </layout>
            </widget>
           </item>
           <item row="0" column="0">
            <widget class="QFrame" name="frame_8">
             <property name="frameShape">
              <enum>QFrame::NoFrame</enum>
             </property>
             <property name="frameShadow">
              <enum>QFrame::Raised</enum>
             </property>
             <layout class="QGridLayout" name="gridLayout_22">
              <property name="leftMargin">
               <number>0</number>
              </property>
              <property name="topMargin">
               <number>0</number>
              </property>
              <property name="rightMargin">
               <number>0</number>
              </property>
              <property name="bottomMargin">
               <number>0</number>
              </property>
              <item row="0" column="0">
               <widget class="QCheckBox" name="m_RealTimeFibers">
                <property name="toolTip">
                 <string>Disable to only generate fibers if &quot;Generate Fibers&quot; button is pressed.</string>
                </property>
                <property name="text">
                 <string>Real Time Fibers</string>
                </property>
                <property name="checked">
                 <bool>true</bool>
                </property>
               </widget>
              </item>
              <item row="0" column="1">
               <widget class="QCheckBox" name="m_AdvancedOptionsBox">
                <property name="toolTip">
                 <string>Disable to only generate fibers if &quot;Generate Fibers&quot; button is pressed.</string>
                </property>
                <property name="text">
                 <string>Advanced Options</string>
                </property>
                <property name="checked">
                 <bool>false</bool>
                </property>
               </widget>
              </item>
             </layout>
            </widget>
           </item>
          </layout>
         </widget>
        </item>
        <item row="3" column="0">
         <widget class="QFrame" name="frame">
          <property name="frameShape">
           <enum>QFrame::NoFrame</enum>
          </property>
          <property name="frameShadow">
           <enum>QFrame::Raised</enum>
          </property>
          <layout class="QGridLayout" name="gridLayout_3">
           <property name="leftMargin">
            <number>0</number>
           </property>
           <property name="topMargin">
            <number>0</number>
           </property>
           <property name="rightMargin">
            <number>0</number>
           </property>
           <property name="bottomMargin">
            <number>0</number>
           </property>
           <item row="0" column="0">
            <widget class="QPushButton" name="m_CircleButton">
             <property name="enabled">
              <bool>false</bool>
             </property>
             <property name="maximumSize">
              <size>
               <width>30</width>
               <height>30</height>
              </size>
             </property>
             <property name="toolTip">
              <string>Draw elliptical fiducial.</string>
             </property>
             <property name="text">
              <string/>
             </property>
             <property name="icon">
              <iconset resource="../../resources/QmitkDiffusionImaging.qrc">
               <normaloff>:/QmitkDiffusionImaging/circle.png</normaloff>:/QmitkDiffusionImaging/circle.png</iconset>
             </property>
             <property name="iconSize">
              <size>
               <width>32</width>
               <height>32</height>
              </size>
             </property>
             <property name="checkable">
              <bool>false</bool>
             </property>
             <property name="flat">
              <bool>true</bool>
             </property>
            </widget>
           </item>
           <item row="0" column="1">
            <widget class="QPushButton" name="m_FlipButton">
             <property name="enabled">
              <bool>false</bool>
             </property>
             <property name="maximumSize">
              <size>
               <width>30</width>
               <height>30</height>
              </size>
             </property>
             <property name="toolTip">
              <string>Flip fiber waypoints of selcted fiducial around one axis.</string>
             </property>
             <property name="text">
              <string/>
             </property>
             <property name="icon">
              <iconset resource="../../resources/QmitkDiffusionImaging.qrc">
               <normaloff>:/QmitkDiffusionImaging/refresh.xpm</normaloff>:/QmitkDiffusionImaging/refresh.xpm</iconset>
             </property>
             <property name="iconSize">
              <size>
               <width>32</width>
               <height>32</height>
              </size>
             </property>
             <property name="checkable">
              <bool>false</bool>
             </property>
             <property name="flat">
              <bool>true</bool>
             </property>
            </widget>
           </item>
           <item row="0" column="2">
            <spacer name="horizontalSpacer">
             <property name="orientation">
              <enum>Qt::Horizontal</enum>
             </property>
             <property name="sizeHint" stdset="0">
              <size>
               <width>40</width>
               <height>20</height>
              </size>
             </property>
            </spacer>
           </item>
          </layout>
         </widget>
        </item>
       </layout>
      </widget>
      <widget class="QWidget" name="tab_2">
       <attribute name="title">
        <string>Signal Generation</string>
       </attribute>
       <layout class="QGridLayout" name="gridLayout_4">
        <item row="10" column="0">
         <widget class="QGroupBox" name="groupBox_6">
          <property name="title">
           <string>Extra-axonal Compartments</string>
          </property>
          <layout class="QGridLayout" name="gridLayout_14">
           <item row="17" column="0">
            <widget class="QFrame" name="m_Comp4FractionFrame">
             <property name="frameShape">
              <enum>QFrame::NoFrame</enum>
             </property>
             <property name="frameShadow">
              <enum>QFrame::Raised</enum>
             </property>
             <layout class="QGridLayout" name="gridLayout_18">
              <property name="leftMargin">
               <number>0</number>
              </property>
              <property name="topMargin">
               <number>0</number>
              </property>
              <property name="rightMargin">
               <number>0</number>
              </property>
              <property name="bottomMargin">
               <number>0</number>
              </property>
              <item row="0" column="0">
               <widget class="QLabel" name="m_NoiseLabel_3">
                <property name="text">
                 <string>Volume Fraction:</string>
                </property>
               </widget>
              </item>
              <item row="0" column="1">
               <widget class="QmitkDataStorageComboBox" name="m_Comp4VolumeFraction">
                <property name="toolTip">
                 <string/>
                </property>
               </widget>
              </item>
             </layout>
            </widget>
           </item>
           <item row="6" column="0">
            <widget class="QComboBox" name="m_Compartment3Box">
             <property name="toolTip">
              <string>Select signal model for extra-axonal compartment.</string>
             </property>
             <item>
              <property name="text">
               <string>Ball Model</string>
              </property>
             </item>
             <item>
              <property name="text">
               <string>Astrosticks Model</string>
              </property>
             </item>
             <item>
              <property name="text">
               <string>Dot Model</string>
              </property>
             </item>
             <item>
              <property name="text">
               <string>Prototype Signal</string>
              </property>
             </item>
            </widget>
           </item>
           <item row="8" column="0">
            <widget class="QmitkAstrosticksModelParametersWidget" name="m_AstrosticksWidget1" native="true"/>
           </item>
           <item row="10" column="0">
            <widget class="QmitkPrototypeSignalParametersWidget" name="m_PrototypeWidget3" native="true"/>
           </item>
           <item row="15" column="0">
            <widget class="QmitkDotModelParametersWidget" name="m_DotWidget2" native="true"/>
           </item>
           <item row="9" column="0">
            <widget class="QmitkDotModelParametersWidget" name="m_DotWidget1" native="true"/>
           </item>
           <item row="11" column="0">
            <widget class="Line" name="line_2">
             <property name="orientation">
              <enum>Qt::Horizontal</enum>
             </property>
            </widget>
           </item>
           <item row="13" column="0">
            <widget class="QmitkBallModelParametersWidget" name="m_BallWidget2" native="true"/>
           </item>
           <item row="7" column="0">
            <widget class="QmitkBallModelParametersWidget" name="m_BallWidget1" native="true"/>
           </item>
           <item row="14" column="0">
            <widget class="QmitkAstrosticksModelParametersWidget" name="m_AstrosticksWidget2" native="true"/>
           </item>
           <item row="12" column="0">
            <widget class="QComboBox" name="m_Compartment4Box">
             <property name="toolTip">
              <string>Select signal model for extra-axonal compartment.</string>
             </property>
             <item>
              <property name="text">
               <string>--</string>
              </property>
             </item>
             <item>
              <property name="text">
               <string>Ball Model</string>
              </property>
             </item>
             <item>
              <property name="text">
               <string>Astrosticks Model</string>
              </property>
             </item>
             <item>
              <property name="text">
               <string>Dot Model</string>
              </property>
             </item>
             <item>
              <property name="text">
               <string>Prototype Signal</string>
              </property>
             </item>
            </widget>
           </item>
           <item row="16" column="0">
            <widget class="QmitkPrototypeSignalParametersWidget" name="m_PrototypeWidget4" native="true"/>
           </item>
          </layout>
         </widget>
        </item>
        <item row="13" column="0">
         <spacer name="verticalSpacer_2">
          <property name="orientation">
           <enum>Qt::Vertical</enum>
          </property>
          <property name="sizeHint" stdset="0">
           <size>
            <width>20</width>
            <height>40</height>
           </size>
          </property>
         </spacer>
        </item>
        <item row="7" column="0">
         <widget class="QGroupBox" name="groupBox">
          <property name="title">
           <string>Image Settings</string>
          </property>
          <layout class="QGridLayout" name="gridLayout">
           <item row="6" column="0">
            <widget class="QCheckBox" name="m_AdvancedOptionsBox_2">
             <property name="text">
              <string>Advanced Options</string>
             </property>
            </widget>
           </item>
           <item row="5" column="0">
            <widget class="QFrame" name="m_TensorsToDWIFrame">
             <property name="frameShape">
              <enum>QFrame::NoFrame</enum>
             </property>
             <property name="frameShadow">
              <enum>QFrame::Raised</enum>
             </property>
             <layout class="QGridLayout" name="gridLayout_24">
              <property name="leftMargin">
               <number>0</number>
              </property>
              <property name="topMargin">
               <number>0</number>
              </property>
              <property name="rightMargin">
               <number>0</number>
              </property>
              <property name="bottomMargin">
               <number>0</number>
              </property>
              <property name="spacing">
               <number>6</number>
              </property>
              <item row="0" column="0">
               <widget class="QLabel" name="m_TensorsToDWINumDirsLabel">
                <property name="text">
                 <string>Gradient Directions:</string>
                </property>
               </widget>
              </item>
              <item row="0" column="1">
               <widget class="QSpinBox" name="m_NumGradientsBox">
                <property name="toolTip">
                 <string>Number of gradient directions distributed over the half sphere.</string>
                </property>
                <property name="minimum">
                 <number>0</number>
                </property>
                <property name="maximum">
                 <number>10000</number>
                </property>
                <property name="singleStep">
                 <number>1</number>
                </property>
                <property name="value">
                 <number>30</number>
                </property>
               </widget>
              </item>
              <item row="1" column="0">
               <widget class="QLabel" name="m_TensorsToDWIBValueLabel">
                <property name="toolTip">
                 <string/>
                </property>
                <property name="statusTip">
                 <string/>
                </property>
                <property name="whatsThis">
                 <string/>
                </property>
                <property name="text">
                 <string>&lt;html&gt;&lt;head/&gt;&lt;body&gt;&lt;p&gt;b-Value&lt;span style=&quot; font-style:italic;&quot;&gt; [s/mm&lt;/span&gt;&lt;span style=&quot; font-style:italic; vertical-align:super;&quot;&gt;2&lt;/span&gt;&lt;span style=&quot; font-style:italic;&quot;&gt;]&lt;/span&gt;:&lt;/p&gt;&lt;/body&gt;&lt;/html&gt;</string>
                </property>
                <property name="wordWrap">
                 <bool>false</bool>
                </property>
               </widget>
              </item>
              <item row="1" column="1">
               <widget class="QSpinBox" name="m_BvalueBox">
                <property name="toolTip">
                 <string>b-value in s/mm²</string>
                </property>
                <property name="minimum">
                 <number>0</number>
                </property>
                <property name="maximum">
                 <number>10000</number>
                </property>
                <property name="singleStep">
                 <number>100</number>
                </property>
                <property name="value">
                 <number>1000</number>
                </property>
               </widget>
              </item>
             </layout>
            </widget>
           </item>
           <item row="2" column="0">
            <widget class="QLabel" name="m_GeometryMessage">
             <property name="styleSheet">
              <string notr="true">color: rgb(255, 0, 0);</string>
             </property>
             <property name="text">
              <string>Using  geometry of selected image!</string>
             </property>
            </widget>
           </item>
           <item row="4" column="0">
            <widget class="QLabel" name="m_DiffusionPropsMessage">
             <property name="styleSheet">
              <string notr="true">color: rgb(255, 0, 0);</string>
             </property>
             <property name="text">
              <string>Using  gradients of selected DWI!</string>
             </property>
            </widget>
           </item>
           <item row="7" column="0">
            <widget class="QFrame" name="m_AdvancedSignalOptionsFrame">
             <property name="frameShape">
              <enum>QFrame::NoFrame</enum>
             </property>
             <property name="frameShadow">
              <enum>QFrame::Raised</enum>
             </property>
             <layout class="QGridLayout" name="gridLayout_23">
              <property name="leftMargin">
               <number>0</number>
              </property>
              <property name="topMargin">
               <number>0</number>
              </property>
              <property name="rightMargin">
               <number>0</number>
              </property>
              <property name="bottomMargin">
               <number>0</number>
              </property>
              <property name="horizontalSpacing">
               <number>6</number>
              </property>
              <item row="0" column="1">
               <widget class="QSpinBox" name="m_SignalScaleBox">
                <property name="toolTip">
                 <string>TE in milliseconds</string>
                </property>
                <property name="minimum">
                 <number>1</number>
                </property>
                <property name="maximum">
                 <number>10000</number>
                </property>
                <property name="singleStep">
                 <number>1</number>
                </property>
                <property name="value">
                 <number>100</number>
                </property>
               </widget>
              </item>
              <item row="1" column="0">
               <widget class="QLabel" name="m_TensorsToDWIBValueLabel_13">
                <property name="toolTip">
                 <string/>
                </property>
                <property name="statusTip">
                 <string/>
                </property>
                <property name="whatsThis">
                 <string/>
                </property>
                <property name="text">
                 <string>&lt;html&gt;&lt;head/&gt;&lt;body&gt;&lt;p&gt;Echo Time &lt;span style=&quot; font-style:italic;&quot;&gt;TE&lt;/span&gt;:  &lt;/p&gt;&lt;/body&gt;&lt;/html&gt;</string>
                </property>
                <property name="wordWrap">
                 <bool>false</bool>
                </property>
               </widget>
              </item>
              <item row="2" column="1">
               <widget class="QDoubleSpinBox" name="m_LineReadoutTimeBox">
                <property name="toolTip">
                 <string>T2* relaxation time (in milliseconds).</string>
                </property>
                <property name="maximum">
                 <double>100.000000000000000</double>
                </property>
                <property name="singleStep">
                 <double>0.100000000000000</double>
                </property>
                <property name="value">
                 <double>1.000000000000000</double>
                </property>
               </widget>
              </item>
              <item row="9" column="0">
               <widget class="QCheckBox" name="m_VolumeFractionsBox">
                <property name="toolTip">
                 <string>Output one image per compartment containing the corresponding volume fractions per voxel.</string>
                </property>
                <property name="text">
                 <string>Output Volume Fractions</string>
                </property>
                <property name="checked">
                 <bool>false</bool>
                </property>
               </widget>
              </item>
              <item row="5" column="1">
               <widget class="QComboBox" name="m_DiffusionDirectionBox">
                <item>
                 <property name="text">
                  <string>Fiber tangent</string>
                 </property>
                </item>
                <item>
                 <property name="text">
                  <string>Main fiber directions</string>
                 </property>
                </item>
                <item>
                 <property name="text">
                  <string>Random</string>
                 </property>
                </item>
               </widget>
              </item>
              <item row="7" column="0">
               <widget class="QCheckBox" name="m_RelaxationBox">
                <property name="toolTip">
                 <string>&lt;html&gt;&lt;head/&gt;&lt;body&gt;&lt;p&gt;&lt;span style=&quot; font-style:italic;&quot;&gt;TE&lt;/span&gt;, &lt;span style=&quot; font-style:italic;&quot;&gt;T&lt;/span&gt;&lt;span style=&quot; font-style:italic; vertical-align:sub;&quot;&gt;inhom&lt;/span&gt; and &lt;span style=&quot; font-style:italic;&quot;&gt;T2&lt;/span&gt; will have no effect if unchecked.&lt;/p&gt;&lt;/body&gt;&lt;/html&gt;</string>
                </property>
                <property name="text">
                 <string>Simulate Signal Relaxation</string>
                </property>
                <property name="checked">
                 <bool>true</bool>
                </property>
               </widget>
              </item>
              <item row="4" column="0">
               <widget class="QLabel" name="m_TensorsToDWINumDirsLabel_4">
                <property name="text">
                 <string>Fiber Radius:</string>
                </property>
               </widget>
              </item>
              <item row="2" column="0">
               <widget class="QLabel" name="m_TensorsToDWIBValueLabel_15">
                <property name="toolTip">
                 <string/>
                </property>
                <property name="statusTip">
                 <string/>
                </property>
                <property name="whatsThis">
                 <string/>
                </property>
                <property name="text">
                 <string>Line Readout Time:  </string>
                </property>
                <property name="wordWrap">
                 <bool>false</bool>
                </property>
               </widget>
              </item>
              <item row="3" column="0">
               <widget class="QLabel" name="m_TensorsToDWIBValueLabel_12">
                <property name="toolTip">
                 <string/>
                </property>
                <property name="statusTip">
                 <string/>
                </property>
                <property name="whatsThis">
                 <string/>
                </property>
                <property name="text">
                 <string>&lt;html&gt;&lt;head/&gt;&lt;body&gt;&lt;p&gt;&lt;span style=&quot; font-style:italic;&quot;&gt;T&lt;/span&gt;&lt;span style=&quot; font-style:italic; vertical-align:sub;&quot;&gt;inhom&lt;/span&gt; Relaxation: &lt;/p&gt;&lt;/body&gt;&lt;/html&gt;</string>
                </property>
                <property name="wordWrap">
                 <bool>false</bool>
                </property>
               </widget>
              </item>
              <item row="5" column="0">
               <widget class="QLabel" name="label_3">
                <property name="text">
                 <string>Diffusion Direction:</string>
                </property>
               </widget>
              </item>
              <item row="3" column="1">
               <widget class="QSpinBox" name="m_T2starBox">
                <property name="toolTip">
                 <string>Relaxation time due to magnetic field inhomogeneities (T2', in milliseconds).</string>
                </property>
                <property name="minimum">
                 <number>1</number>
                </property>
                <property name="maximum">
                 <number>10000</number>
                </property>
                <property name="singleStep">
                 <number>1</number>
                </property>
                <property name="value">
                 <number>50</number>
                </property>
               </widget>
              </item>
              <item row="1" column="1">
               <widget class="QSpinBox" name="m_TEbox">
                <property name="toolTip">
                 <string>TE in milliseconds</string>
                </property>
                <property name="minimum">
                 <number>1</number>
                </property>
                <property name="maximum">
                 <number>10000</number>
                </property>
                <property name="singleStep">
                 <number>1</number>
                </property>
                <property name="value">
                 <number>100</number>
                </property>
               </widget>
              </item>
              <item row="0" column="0">
               <widget class="QLabel" name="m_TensorsToDWINumDirsLabel_5">
                <property name="text">
                 <string>Signal Scale:</string>
                </property>
               </widget>
              </item>
              <item row="4" column="1">
               <widget class="QSpinBox" name="m_FiberRadius">
                <property name="toolTip">
                 <string>Fiber radius used to calculate volume fractions (in µm). Set to 0 for automatic radius estimation.</string>
                </property>
                <property name="minimum">
                 <number>0</number>
                </property>
                <property name="maximum">
                 <number>1000</number>
                </property>
                <property name="value">
                 <number>0</number>
                </property>
               </widget>
              </item>
              <item row="6" column="0">
               <widget class="QLabel" name="label_4">
                <property name="text">
                 <string>Separation Angle:</string>
                </property>
               </widget>
              </item>
              <item row="8" column="0">
               <widget class="QCheckBox" name="m_EnforcePureFiberVoxelsBox">
                <property name="toolTip">
                 <string>Disable partial volume. Treat voxel content as fiber-only if at least one fiber is present.</string>
                </property>
                <property name="text">
                 <string>Disable Partial Volume Effects</string>
                </property>
                <property name="checked">
                 <bool>false</bool>
                </property>
               </widget>
              </item>
              <item row="6" column="1">
               <widget class="QDoubleSpinBox" name="m_SeparationAngleBox">
                <property name="decimals">
                 <number>1</number>
                </property>
                <property name="maximum">
                 <double>90.000000000000000</double>
                </property>
                <property name="value">
                 <double>45.000000000000000</double>
                </property>
               </widget>
              </item>
             </layout>
            </widget>
           </item>
           <item row="3" column="0">
            <widget class="QFrame" name="m_GeometryFrame">
             <property name="frameShape">
              <enum>QFrame::NoFrame</enum>
             </property>
             <property name="frameShadow">
              <enum>QFrame::Raised</enum>
             </property>
             <layout class="QGridLayout" name="gridLayout_7">
              <property name="leftMargin">
               <number>0</number>
              </property>
              <property name="topMargin">
               <number>0</number>
              </property>
              <property name="rightMargin">
               <number>0</number>
              </property>
              <property name="bottomMargin">
               <number>0</number>
              </property>
              <item row="2" column="2">
               <widget class="QDoubleSpinBox" name="m_SpacingY">
                <property name="decimals">
                 <number>3</number>
                </property>
                <property name="minimum">
                 <double>0.100000000000000</double>
                </property>
                <property name="maximum">
                 <double>50.000000000000000</double>
                </property>
                <property name="singleStep">
                 <double>0.100000000000000</double>
                </property>
                <property name="value">
                 <double>2.000000000000000</double>
                </property>
               </widget>
              </item>
              <item row="2" column="0">
               <widget class="QLabel" name="label_2">
                <property name="text">
                 <string>Image Spacing:</string>
                </property>
               </widget>
              </item>
              <item row="2" column="3">
               <widget class="QDoubleSpinBox" name="m_SpacingZ">
                <property name="decimals">
                 <number>3</number>
                </property>
                <property name="minimum">
                 <double>0.100000000000000</double>
                </property>
                <property name="maximum">
                 <double>50.000000000000000</double>
                </property>
                <property name="singleStep">
                 <double>0.100000000000000</double>
                </property>
                <property name="value">
                 <double>2.000000000000000</double>
                </property>
               </widget>
              </item>
              <item row="2" column="1">
               <widget class="QDoubleSpinBox" name="m_SpacingX">
                <property name="decimals">
                 <number>3</number>
                </property>
                <property name="minimum">
                 <double>0.100000000000000</double>
                </property>
                <property name="maximum">
                 <double>50.000000000000000</double>
                </property>
                <property name="singleStep">
                 <double>0.100000000000000</double>
                </property>
                <property name="value">
                 <double>2.000000000000000</double>
                </property>
               </widget>
              </item>
              <item row="0" column="0">
               <widget class="QLabel" name="label">
                <property name="text">
                 <string>Image Dimensions:</string>
                </property>
               </widget>
              </item>
              <item row="0" column="1">
               <widget class="QSpinBox" name="m_SizeX">
                <property name="toolTip">
                 <string>Fiber sampling factor which determines the accuracy of the calculated fiber and non-fiber volume fractions.</string>
                </property>
                <property name="minimum">
                 <number>1</number>
                </property>
                <property name="maximum">
                 <number>1000</number>
                </property>
                <property name="singleStep">
                 <number>1</number>
                </property>
                <property name="value">
                 <number>11</number>
                </property>
               </widget>
              </item>
              <item row="0" column="2">
               <widget class="QSpinBox" name="m_SizeY">
                <property name="toolTip">
                 <string>Fiber sampling factor which determines the accuracy of the calculated fiber and non-fiber volume fractions.</string>
                </property>
                <property name="minimum">
                 <number>1</number>
                </property>
                <property name="maximum">
                 <number>1000</number>
                </property>
                <property name="singleStep">
                 <number>1</number>
                </property>
                <property name="value">
                 <number>11</number>
                </property>
               </widget>
              </item>
              <item row="0" column="3">
               <widget class="QSpinBox" name="m_SizeZ">
                <property name="toolTip">
                 <string>Fiber sampling factor which determines the accuracy of the calculated fiber and non-fiber volume fractions.</string>
                </property>
                <property name="minimum">
                 <number>1</number>
                </property>
                <property name="maximum">
                 <number>1000</number>
                </property>
                <property name="singleStep">
                 <number>1</number>
                </property>
                <property name="value">
                 <number>3</number>
                </property>
               </widget>
              </item>
             </layout>
            </widget>
           </item>
          </layout>
         </widget>
        </item>
        <item row="9" column="0">
         <widget class="QGroupBox" name="groupBox_5">
          <property name="title">
           <string>Inter-axonal Compartment</string>
          </property>
          <layout class="QGridLayout" name="gridLayout_17">
           <item row="0" column="0">
            <widget class="QComboBox" name="m_Compartment2Box">
             <property name="toolTip">
              <string>Select signal model for intra-axonal compartment.</string>
             </property>
             <item>
              <property name="text">
               <string>--</string>
              </property>
             </item>
             <item>
              <property name="text">
               <string>Stick Model</string>
              </property>
             </item>
             <item>
              <property name="text">
               <string>Zeppelin Model</string>
              </property>
             </item>
             <item>
              <property name="text">
               <string>Tensor Model</string>
              </property>
             </item>
            </widget>
           </item>
           <item row="1" column="0">
            <widget class="QmitkZeppelinModelParametersWidget" name="m_ZeppelinWidget2" native="true"/>
           </item>
           <item row="2" column="0">
            <widget class="QmitkStickModelParametersWidget" name="m_StickWidget2" native="true"/>
           </item>
           <item row="3" column="0">
            <widget class="QmitkTensorModelParametersWidget" name="m_TensorWidget2" native="true"/>
           </item>
           <item row="4" column="0">
            <widget class="QmitkPrototypeSignalParametersWidget" name="m_PrototypeWidget2" native="true"/>
           </item>
          </layout>
         </widget>
        </item>
        <item row="3" column="0">
         <widget class="QCommandLinkButton" name="m_AbortSimulationButton">
          <property name="enabled">
           <bool>true</bool>
          </property>
          <property name="toolTip">
           <string>Stop current simulation.</string>
          </property>
          <property name="text">
           <string>Abort Simulation</string>
          </property>
          <property name="icon">
           <iconset resource="../../resources/QmitkDiffusionImaging.qrc">
            <normaloff>:/QmitkDiffusionImaging/general_icons/abort.ico</normaloff>:/QmitkDiffusionImaging/general_icons/abort.ico</iconset>
          </property>
         </widget>
        </item>
        <item row="0" column="0" rowspan="2">
         <widget class="QGroupBox" name="groupBox_2">
          <property name="title">
           <string>Data</string>
          </property>
          <layout class="QGridLayout" name="gridLayout_10">
           <item row="4" column="2">
            <widget class="QFrame" name="frame_6">
             <property name="frameShape">
              <enum>QFrame::NoFrame</enum>
             </property>
             <property name="frameShadow">
              <enum>QFrame::Raised</enum>
             </property>
             <layout class="QGridLayout" name="gridLayout_20">
              <property name="leftMargin">
               <number>0</number>
              </property>
              <property name="topMargin">
               <number>0</number>
              </property>
              <property name="rightMargin">
               <number>0</number>
              </property>
              <property name="bottomMargin">
               <number>0</number>
              </property>
              <property name="spacing">
               <number>0</number>
              </property>
              <item row="0" column="0">
               <widget class="QLineEdit" name="m_SavePathEdit">
                <property name="text">
                 <string>-</string>
                </property>
               </widget>
              </item>
              <item row="0" column="1">
               <widget class="QToolButton" name="m_OutputPathButton">
                <property name="text">
                 <string>...</string>
                </property>
               </widget>
              </item>
             </layout>
            </widget>
           </item>
           <item row="2" column="2">
            <widget class="QmitkDataStorageComboBoxWithSelectNone" name="m_MaskComboBox">
             <property name="toolTip">
              <string>&lt;html&gt;&lt;head/&gt;&lt;body&gt;&lt;p&gt;Select a binary image to define the area of signal generation. Outside of the mask image only noise will be actively generated.&lt;/p&gt;&lt;/body&gt;&lt;/html&gt;</string>
             </property>
+            <property name="sizeAdjustPolicy">
+             <enum>QComboBox::AdjustToMinimumContentsLength</enum>
+            </property>
            </widget>
           </item>
           <item row="0" column="0" rowspan="2" colspan="2">
            <widget class="QLabel" name="m_TensorsToDWIBValueLabel_16">
             <property name="toolTip">
              <string/>
             </property>
             <property name="statusTip">
              <string/>
             </property>
             <property name="whatsThis">
              <string/>
             </property>
             <property name="text">
              <string>Fiber Bundle:</string>
             </property>
             <property name="wordWrap">
              <bool>false</bool>
             </property>
            </widget>
           </item>
           <item row="4" column="0">
            <widget class="QLabel" name="m_TensorsToDWIBValueLabel_10">
             <property name="toolTip">
              <string/>
             </property>
             <property name="statusTip">
              <string/>
             </property>
             <property name="whatsThis">
              <string/>
             </property>
             <property name="text">
              <string>Save path:</string>
             </property>
             <property name="wordWrap">
              <bool>false</bool>
             </property>
            </widget>
           </item>
           <item row="2" column="0">
            <widget class="QLabel" name="m_TensorsToDWIBValueLabel_3">
             <property name="toolTip">
              <string/>
             </property>
             <property name="statusTip">
              <string/>
             </property>
             <property name="whatsThis">
              <string/>
             </property>
             <property name="text">
              <string>Tissue Mask:</string>
             </property>
             <property name="wordWrap">
              <bool>false</bool>
             </property>
            </widget>
           </item>
           <item row="1" column="2">
            <widget class="QmitkDataStorageComboBoxWithSelectNone" name="m_FiberBundleComboBox">
             <property name="toolTip">
              <string>&lt;html&gt;&lt;head/&gt;&lt;body&gt;&lt;p&gt;Select a fiber bundle to generate the white matter signal from. You can either use the fiber definition tab to manually define an input fiber bundle or you can also use any existing bundle, e.g. yielded by a tractography algorithm.&lt;/p&gt;&lt;/body&gt;&lt;/html&gt;</string>
             </property>
+            <property name="sizeAdjustPolicy">
+             <enum>QComboBox::AdjustToMinimumContentsLength</enum>
+            </property>
            </widget>
           </item>
           <item row="3" column="0">
            <widget class="QLabel" name="m_TensorsToDWIBValueLabel_11">
             <property name="toolTip">
              <string/>
             </property>
             <property name="statusTip">
              <string/>
             </property>
             <property name="whatsThis">
              <string/>
             </property>
             <property name="text">
              <string>Template Image:</string>
             </property>
             <property name="wordWrap">
              <bool>false</bool>
             </property>
            </widget>
           </item>
           <item row="3" column="2">
            <widget class="QmitkDataStorageComboBoxWithSelectNone" name="m_TemplateComboBox">
             <property name="toolTip">
              <string>&lt;html&gt;&lt;head/&gt;&lt;body&gt;&lt;p&gt;The parameters for the simulation (e.g. spacing, size, diffuison-weighted gradients, b-value) are adopted from this image.&lt;/p&gt;&lt;/body&gt;&lt;/html&gt;</string>
             </property>
+            <property name="sizeAdjustPolicy">
+             <enum>QComboBox::AdjustToMinimumContentsLength</enum>
+            </property>
            </widget>
           </item>
          </layout>
         </widget>
        </item>
        <item row="4" column="0">
         <widget class="QTextEdit" name="m_SimulationStatusText">
          <property name="font">
           <font>
            <pointsize>8</pointsize>
           </font>
          </property>
          <property name="readOnly">
           <bool>true</bool>
          </property>
         </widget>
        </item>
        <item row="12" column="0">
         <widget class="QGroupBox" name="groupBox_3">
          <property name="title">
           <string>Noise and other Artifacts</string>
          </property>
          <layout class="QGridLayout" name="gridLayout_6">
           <item row="20" column="0">
            <widget class="Line" name="line">
             <property name="orientation">
              <enum>Qt::Horizontal</enum>
             </property>
            </widget>
           </item>
           <item row="0" column="0">
            <widget class="QCheckBox" name="m_AddNoise">
             <property name="text">
              <string>Add Noise</string>
             </property>
             <property name="checked">
              <bool>false</bool>
             </property>
            </widget>
           </item>
           <item row="21" column="0">
            <widget class="QCheckBox" name="m_AddGibbsRinging">
             <property name="toolTip">
              <string>Add ringing artifacts occuring at strong edges in the image.</string>
             </property>
             <property name="text">
              <string>Add Gibbs Ringing</string>
             </property>
             <property name="checked">
              <bool>false</bool>
             </property>
            </widget>
           </item>
           <item row="10" column="0">
            <widget class="QFrame" name="m_AliasingFrame">
             <property name="enabled">
              <bool>true</bool>
             </property>
             <property name="frameShape">
              <enum>QFrame::NoFrame</enum>
             </property>
             <property name="frameShadow">
              <enum>QFrame::Raised</enum>
             </property>
             <layout class="QFormLayout" name="formLayout_10">
              <property name="horizontalSpacing">
               <number>6</number>
              </property>
              <property name="leftMargin">
               <number>0</number>
              </property>
              <property name="topMargin">
               <number>0</number>
              </property>
              <property name="rightMargin">
               <number>0</number>
              </property>
              <property name="bottomMargin">
               <number>0</number>
              </property>
              <item row="0" column="0">
               <widget class="QLabel" name="m_TensorsToDWIBValueLabel_27">
                <property name="toolTip">
                 <string/>
                </property>
                <property name="statusTip">
                 <string/>
                </property>
                <property name="whatsThis">
                 <string/>
                </property>
                <property name="text">
                 <string>Shrink FOV (%):</string>
                </property>
                <property name="wordWrap">
                 <bool>false</bool>
                </property>
               </widget>
              </item>
              <item row="0" column="1">
               <widget class="QDoubleSpinBox" name="m_WrapBox">
                <property name="toolTip">
                 <string>Shrink FOV by this percentage.</string>
                </property>
                <property name="decimals">
                 <number>1</number>
                </property>
                <property name="minimum">
                 <double>0.000000000000000</double>
                </property>
                <property name="maximum">
                 <double>90.000000000000000</double>
                </property>
                <property name="singleStep">
                 <double>0.100000000000000</double>
                </property>
                <property name="value">
                 <double>25.000000000000000</double>
                </property>
               </widget>
              </item>
             </layout>
            </widget>
           </item>
           <item row="17" column="0">
            <widget class="Line" name="line_4">
             <property name="orientation">
              <enum>Qt::Horizontal</enum>
             </property>
            </widget>
           </item>
           <item row="4" column="0">
            <widget class="QFrame" name="m_SpikeFrame">
             <property name="frameShape">
              <enum>QFrame::NoFrame</enum>
             </property>
             <property name="frameShadow">
              <enum>QFrame::Raised</enum>
             </property>
             <layout class="QFormLayout" name="formLayout_9">
              <property name="leftMargin">
               <number>0</number>
              </property>
              <property name="topMargin">
               <number>0</number>
              </property>
              <property name="rightMargin">
               <number>0</number>
              </property>
              <property name="bottomMargin">
               <number>0</number>
              </property>
              <item row="0" column="0">
               <widget class="QLabel" name="m_NoiseLabel_2">
                <property name="text">
                 <string>Num. Spikes:</string>
                </property>
               </widget>
              </item>
              <item row="0" column="1">
               <widget class="QSpinBox" name="m_SpikeNumBox">
                <property name="toolTip">
                 <string>The number of randomly occurring signal spikes.</string>
                </property>
                <property name="value">
                 <number>1</number>
                </property>
               </widget>
              </item>
              <item row="1" column="1">
               <widget class="QDoubleSpinBox" name="m_SpikeScaleBox">
                <property name="toolTip">
                 <string>Spike amplitude relative to the largest signal amplitude of the corresponding k-space slice.</string>
                </property>
                <property name="singleStep">
                 <double>0.100000000000000</double>
                </property>
                <property name="value">
                 <double>0.100000000000000</double>
                </property>
               </widget>
              </item>
              <item row="1" column="0">
               <widget class="QLabel" name="m_NoiseLabel_4">
                <property name="text">
                 <string>Scale:</string>
                </property>
               </widget>
              </item>
             </layout>
            </widget>
           </item>
           <item row="18" column="0">
            <widget class="QCheckBox" name="m_AddEddy">
             <property name="toolTip">
              <string>!!!EXPERIMENTAL!!!</string>
             </property>
             <property name="text">
              <string>Add Eddy Current Effects</string>
             </property>
             <property name="checked">
              <bool>false</bool>
             </property>
            </widget>
           </item>
           <item row="3" column="0">
            <widget class="QCheckBox" name="m_AddSpikes">
             <property name="text">
              <string>Add Spikes</string>
             </property>
             <property name="checked">
              <bool>false</bool>
             </property>
            </widget>
           </item>
           <item row="1" column="0">
            <widget class="QFrame" name="m_NoiseFrame">
             <property name="frameShape">
              <enum>QFrame::NoFrame</enum>
             </property>
             <property name="frameShadow">
              <enum>QFrame::Raised</enum>
             </property>
             <layout class="QFormLayout" name="formLayout_5">
              <property name="leftMargin">
               <number>0</number>
              </property>
              <property name="topMargin">
               <number>0</number>
              </property>
              <property name="rightMargin">
               <number>0</number>
              </property>
              <property name="bottomMargin">
               <number>0</number>
              </property>
              <item row="1" column="0">
               <widget class="QLabel" name="m_NoiseLabel">
                <property name="text">
                 <string>Variance:</string>
                </property>
               </widget>
              </item>
              <item row="1" column="1">
               <widget class="QDoubleSpinBox" name="m_NoiseLevel">
                <property name="toolTip">
                 <string>Variance of selected noise distribution.</string>
                </property>
                <property name="decimals">
                 <number>4</number>
                </property>
                <property name="minimum">
                 <double>0.000000000000000</double>
                </property>
                <property name="maximum">
                 <double>999999999.000000000000000</double>
                </property>
                <property name="singleStep">
                 <double>0.001000000000000</double>
                </property>
                <property name="value">
                 <double>50.000000000000000</double>
                </property>
               </widget>
              </item>
              <item row="0" column="0">
               <widget class="QLabel" name="m_NoiseLabel_5">
                <property name="text">
                 <string>Distribution:</string>
                </property>
               </widget>
              </item>
              <item row="0" column="1">
               <widget class="QComboBox" name="m_NoiseDistributionBox">
                <property name="toolTip">
                 <string>Noise distribution</string>
                </property>
                <item>
                 <property name="text">
                  <string>Rician</string>
                 </property>
                </item>
                <item>
                 <property name="text">
                  <string>Chi-squared</string>
                 </property>
                </item>
               </widget>
              </item>
             </layout>
            </widget>
           </item>
           <item row="6" column="0">
            <widget class="QCheckBox" name="m_AddGhosts">
             <property name="text">
              <string>Add N/2 Ghosts</string>
             </property>
             <property name="checked">
              <bool>false</bool>
             </property>
            </widget>
           </item>
           <item row="13" column="0">
            <widget class="QFrame" name="m_DistortionsFrame">
             <property name="enabled">
              <bool>true</bool>
             </property>
             <property name="frameShape">
              <enum>QFrame::NoFrame</enum>
             </property>
             <property name="frameShadow">
              <enum>QFrame::Raised</enum>
             </property>
             <layout class="QFormLayout" name="formLayout_7">
              <property name="horizontalSpacing">
               <number>6</number>
              </property>
              <property name="leftMargin">
               <number>0</number>
              </property>
              <property name="topMargin">
               <number>0</number>
              </property>
              <property name="rightMargin">
               <number>0</number>
              </property>
              <property name="bottomMargin">
               <number>0</number>
              </property>
              <item row="0" column="0">
               <widget class="QLabel" name="m_TensorsToDWIBValueLabel_25">
                <property name="toolTip">
                 <string/>
                </property>
                <property name="statusTip">
                 <string/>
                </property>
                <property name="whatsThis">
                 <string/>
                </property>
                <property name="text">
                 <string>Frequency Map:</string>
                </property>
                <property name="wordWrap">
                 <bool>false</bool>
                </property>
               </widget>
              </item>
              <item row="0" column="1">
               <widget class="QmitkDataStorageComboBox" name="m_FrequencyMapBox">
                <property name="toolTip">
                 <string>Select image specifying the frequency inhomogeneities (in Hz).</string>
                </property>
               </widget>
              </item>
             </layout>
            </widget>
           </item>
           <item row="14" column="0">
            <widget class="Line" name="line_5">
             <property name="orientation">
              <enum>Qt::Horizontal</enum>
             </property>
            </widget>
           </item>
           <item row="8" column="0">
            <widget class="Line" name="line_7">
             <property name="orientation">
              <enum>Qt::Horizontal</enum>
             </property>
            </widget>
           </item>
           <item row="11" column="0">
            <widget class="Line" name="line_6">
             <property name="orientation">
              <enum>Qt::Horizontal</enum>
             </property>
            </widget>
           </item>
           <item row="16" column="0">
            <widget class="QFrame" name="m_MotionArtifactFrame">
             <property name="enabled">
              <bool>true</bool>
             </property>
             <property name="frameShape">
              <enum>QFrame::NoFrame</enum>
             </property>
             <property name="frameShadow">
              <enum>QFrame::Raised</enum>
             </property>
             <layout class="QFormLayout" name="formLayout_11">
              <property name="fieldGrowthPolicy">
               <enum>QFormLayout::AllNonFixedFieldsGrow</enum>
              </property>
              <property name="horizontalSpacing">
               <number>6</number>
              </property>
              <property name="leftMargin">
               <number>0</number>
              </property>
              <property name="topMargin">
               <number>6</number>
              </property>
              <property name="rightMargin">
               <number>0</number>
              </property>
              <property name="bottomMargin">
               <number>0</number>
              </property>
              <item row="0" column="0">
               <widget class="QCheckBox" name="m_RandomMotion">
                <property name="toolTip">
                 <string>Toggle between random movement and linear movement.</string>
                </property>
                <property name="text">
                 <string>Randomize motion</string>
                </property>
                <property name="checked">
                 <bool>true</bool>
                </property>
               </widget>
              </item>
              <item row="1" column="0" colspan="2">
               <widget class="QGroupBox" name="m_RotationArtifactFrame">
                <property name="title">
                 <string>Rotation</string>
                </property>
                <layout class="QGridLayout" name="gridLayout_19">
                 <property name="leftMargin">
                  <number>0</number>
                 </property>
                 <property name="topMargin">
                  <number>9</number>
                 </property>
                 <property name="rightMargin">
                  <number>0</number>
                 </property>
                 <property name="bottomMargin">
                  <number>0</number>
                 </property>
                 <item row="1" column="0">
                  <widget class="QLabel" name="m_TensorsToDWIBValueLabel_36">
                   <property name="toolTip">
                    <string/>
                   </property>
                   <property name="statusTip">
                    <string/>
                   </property>
                   <property name="whatsThis">
                    <string/>
                   </property>
                   <property name="text">
                    <string>Degree:</string>
                   </property>
                   <property name="wordWrap">
                    <bool>false</bool>
                   </property>
                  </widget>
                 </item>
                 <item row="0" column="1">
                  <widget class="QLabel" name="m_TensorsToDWIBValueLabel_29">
                   <property name="toolTip">
                    <string/>
                   </property>
                   <property name="statusTip">
                    <string/>
                   </property>
                   <property name="whatsThis">
                    <string/>
                   </property>
                   <property name="text">
                    <string>x</string>
                   </property>
                   <property name="wordWrap">
                    <bool>false</bool>
                   </property>
                  </widget>
                 </item>
                 <item row="0" column="0">
                  <widget class="QLabel" name="m_TensorsToDWIBValueLabel_28">
                   <property name="toolTip">
                    <string/>
                   </property>
                   <property name="statusTip">
                    <string/>
                   </property>
                   <property name="whatsThis">
                    <string/>
                   </property>
                   <property name="text">
                    <string>Axis:</string>
                   </property>
                   <property name="wordWrap">
                    <bool>false</bool>
                   </property>
                  </widget>
                 </item>
                 <item row="1" column="1">
                  <widget class="QDoubleSpinBox" name="m_MaxRotationBoxX">
                   <property name="toolTip">
                    <string>Maximum rotation around x-axis.</string>
                   </property>
                   <property name="decimals">
                    <number>1</number>
                   </property>
                   <property name="maximum">
                    <double>360.000000000000000</double>
                   </property>
                   <property name="singleStep">
                    <double>1.000000000000000</double>
                   </property>
                   <property name="value">
                    <double>0.000000000000000</double>
                   </property>
                  </widget>
                 </item>
                 <item row="1" column="3">
                  <widget class="QDoubleSpinBox" name="m_MaxRotationBoxZ">
                   <property name="toolTip">
                    <string>Maximum rotation around z-axis.</string>
                   </property>
                   <property name="decimals">
                    <number>1</number>
                   </property>
                   <property name="maximum">
                    <double>360.000000000000000</double>
                   </property>
                   <property name="singleStep">
                    <double>1.000000000000000</double>
                   </property>
                   <property name="value">
                    <double>15.000000000000000</double>
                   </property>
                  </widget>
                 </item>
                 <item row="0" column="2">
                  <widget class="QLabel" name="m_TensorsToDWIBValueLabel_30">
                   <property name="toolTip">
                    <string/>
                   </property>
                   <property name="statusTip">
                    <string/>
                   </property>
                   <property name="whatsThis">
                    <string/>
                   </property>
                   <property name="text">
                    <string>y</string>
                   </property>
                   <property name="wordWrap">
                    <bool>false</bool>
                   </property>
                  </widget>
                 </item>
                 <item row="0" column="3">
                  <widget class="QLabel" name="m_TensorsToDWIBValueLabel_31">
                   <property name="toolTip">
                    <string/>
                   </property>
                   <property name="statusTip">
                    <string/>
                   </property>
                   <property name="whatsThis">
                    <string/>
                   </property>
                   <property name="text">
                    <string>z</string>
                   </property>
                   <property name="wordWrap">
                    <bool>false</bool>
                   </property>
                  </widget>
                 </item>
                 <item row="1" column="2">
                  <widget class="QDoubleSpinBox" name="m_MaxRotationBoxY">
                   <property name="toolTip">
                    <string>Maximum rotation around y-axis.</string>
                   </property>
                   <property name="decimals">
                    <number>1</number>
                   </property>
                   <property name="maximum">
                    <double>360.000000000000000</double>
                   </property>
                   <property name="singleStep">
                    <double>1.000000000000000</double>
                   </property>
                   <property name="value">
                    <double>0.000000000000000</double>
                   </property>
                  </widget>
                 </item>
                </layout>
               </widget>
              </item>
              <item row="2" column="0" colspan="2">
               <widget class="QGroupBox" name="m_TranslationArtifactFrame">
                <property name="title">
                 <string>Translation</string>
                </property>
                <layout class="QGridLayout" name="gridLayout_28">
                 <property name="leftMargin">
                  <number>0</number>
                 </property>
                 <property name="rightMargin">
                  <number>0</number>
                 </property>
                 <property name="bottomMargin">
                  <number>0</number>
                 </property>
                 <item row="1" column="0">
                  <widget class="QLabel" name="m_TensorsToDWIBValueLabel_48">
                   <property name="toolTip">
                    <string/>
                   </property>
                   <property name="statusTip">
                    <string/>
                   </property>
                   <property name="whatsThis">
                    <string/>
                   </property>
                   <property name="text">
                    <string>Distance:</string>
                   </property>
                   <property name="wordWrap">
                    <bool>false</bool>
                   </property>
                  </widget>
                 </item>
                 <item row="0" column="1">
                  <widget class="QLabel" name="m_TensorsToDWIBValueLabel_51">
                   <property name="toolTip">
                    <string/>
                   </property>
                   <property name="statusTip">
                    <string/>
                   </property>
                   <property name="whatsThis">
                    <string/>
                   </property>
                   <property name="text">
                    <string>x</string>
                   </property>
                   <property name="wordWrap">
                    <bool>false</bool>
                   </property>
                  </widget>
                 </item>
                 <item row="0" column="2">
                  <widget class="QLabel" name="m_TensorsToDWIBValueLabel_52">
                   <property name="toolTip">
                    <string/>
                   </property>
                   <property name="statusTip">
                    <string/>
                   </property>
                   <property name="whatsThis">
                    <string/>
                   </property>
                   <property name="text">
                    <string>y</string>
                   </property>
                   <property name="wordWrap">
                    <bool>false</bool>
                   </property>
                  </widget>
                 </item>
                 <item row="0" column="0">
                  <widget class="QLabel" name="m_TensorsToDWIBValueLabel_47">
                   <property name="toolTip">
                    <string/>
                   </property>
                   <property name="statusTip">
                    <string/>
                   </property>
                   <property name="whatsThis">
                    <string/>
                   </property>
                   <property name="text">
                    <string>Axis:</string>
                   </property>
                   <property name="wordWrap">
                    <bool>false</bool>
                   </property>
                  </widget>
                 </item>
                 <item row="0" column="3">
                  <widget class="QLabel" name="m_TensorsToDWIBValueLabel_53">
                   <property name="toolTip">
                    <string/>
                   </property>
                   <property name="statusTip">
                    <string/>
                   </property>
                   <property name="whatsThis">
                    <string/>
                   </property>
                   <property name="text">
                    <string>z</string>
                   </property>
                   <property name="wordWrap">
                    <bool>false</bool>
                   </property>
                  </widget>
                 </item>
                 <item row="1" column="1">
                  <widget class="QDoubleSpinBox" name="m_MaxTranslationBoxX">
                   <property name="toolTip">
                    <string>Maximum translation along x-axis.</string>
                   </property>
                   <property name="decimals">
                    <number>1</number>
                   </property>
                   <property name="maximum">
                    <double>1000.000000000000000</double>
                   </property>
                   <property name="singleStep">
                    <double>1.000000000000000</double>
                   </property>
                   <property name="value">
                    <double>0.000000000000000</double>
                   </property>
                  </widget>
                 </item>
                 <item row="1" column="2">
                  <widget class="QDoubleSpinBox" name="m_MaxTranslationBoxY">
                   <property name="toolTip">
                    <string>Maximum translation along y-axis.</string>
                   </property>
                   <property name="decimals">
                    <number>1</number>
                   </property>
                   <property name="maximum">
                    <double>1000.000000000000000</double>
                   </property>
                   <property name="singleStep">
                    <double>1.000000000000000</double>
                   </property>
                   <property name="value">
                    <double>0.000000000000000</double>
                   </property>
                  </widget>
                 </item>
                 <item row="1" column="3">
                  <widget class="QDoubleSpinBox" name="m_MaxTranslationBoxZ">
                   <property name="toolTip">
                    <string>Maximum translation along z-axis.</string>
                   </property>
                   <property name="decimals">
                    <number>1</number>
                   </property>
                   <property name="maximum">
                    <double>1000.000000000000000</double>
                   </property>
                   <property name="singleStep">
                    <double>1.000000000000000</double>
                   </property>
                   <property name="value">
                    <double>0.000000000000000</double>
                   </property>
                  </widget>
                 </item>
                </layout>
               </widget>
              </item>
             </layout>
            </widget>
           </item>
           <item row="15" column="0">
            <widget class="QCheckBox" name="m_AddMotion">
             <property name="text">
              <string>Add Motion Artifacts</string>
             </property>
             <property name="checked">
              <bool>false</bool>
             </property>
            </widget>
           </item>
           <item row="12" column="0">
            <widget class="QCheckBox" name="m_AddDistortions">
             <property name="text">
              <string>Add Distortions</string>
             </property>
             <property name="checked">
              <bool>false</bool>
             </property>
            </widget>
           </item>
           <item row="9" column="0">
            <widget class="QCheckBox" name="m_AddAliasing">
             <property name="text">
              <string>Add Aliasing</string>
             </property>
             <property name="checked">
              <bool>false</bool>
             </property>
            </widget>
           </item>
           <item row="7" column="0">
            <widget class="QFrame" name="m_GhostFrame">
             <property name="enabled">
              <bool>true</bool>
             </property>
             <property name="frameShape">
              <enum>QFrame::NoFrame</enum>
             </property>
             <property name="frameShadow">
              <enum>QFrame::Raised</enum>
             </property>
             <layout class="QFormLayout" name="formLayout_6">
              <property name="horizontalSpacing">
               <number>6</number>
              </property>
              <property name="leftMargin">
               <number>0</number>
              </property>
              <property name="topMargin">
               <number>0</number>
              </property>
              <property name="rightMargin">
               <number>0</number>
              </property>
              <property name="bottomMargin">
               <number>0</number>
              </property>
              <item row="0" column="0">
               <widget class="QLabel" name="m_TensorsToDWIBValueLabel_23">
                <property name="toolTip">
                 <string/>
                </property>
                <property name="statusTip">
                 <string/>
                </property>
                <property name="whatsThis">
                 <string/>
                </property>
                <property name="text">
                 <string>K-Space Line Offset:</string>
                </property>
                <property name="wordWrap">
                 <bool>false</bool>
                </property>
               </widget>
              </item>
              <item row="0" column="1">
               <widget class="QDoubleSpinBox" name="m_kOffsetBox">
                <property name="toolTip">
                 <string>A larger offset increases the inensity of the ghost image.</string>
                </property>
                <property name="decimals">
                 <number>3</number>
                </property>
                <property name="maximum">
                 <double>1.000000000000000</double>
                </property>
                <property name="singleStep">
                 <double>0.010000000000000</double>
                </property>
                <property name="value">
                 <double>0.250000000000000</double>
                </property>
               </widget>
              </item>
             </layout>
            </widget>
           </item>
           <item row="19" column="0">
            <widget class="QFrame" name="m_EddyFrame">
             <property name="enabled">
              <bool>true</bool>
             </property>
             <property name="frameShape">
              <enum>QFrame::NoFrame</enum>
             </property>
             <property name="frameShadow">
              <enum>QFrame::Raised</enum>
             </property>
             <layout class="QFormLayout" name="formLayout_8">
              <property name="fieldGrowthPolicy">
               <enum>QFormLayout::AllNonFixedFieldsGrow</enum>
              </property>
              <property name="horizontalSpacing">
               <number>6</number>
              </property>
              <property name="leftMargin">
               <number>0</number>
              </property>
              <property name="topMargin">
               <number>0</number>
              </property>
              <property name="rightMargin">
               <number>0</number>
              </property>
              <property name="bottomMargin">
               <number>0</number>
              </property>
              <item row="1" column="0">
               <widget class="QLabel" name="m_TensorsToDWIBValueLabel_26">
                <property name="toolTip">
                 <string/>
                </property>
                <property name="statusTip">
                 <string/>
                </property>
                <property name="whatsThis">
                 <string/>
                </property>
                <property name="text">
                 <string>Magnitude:</string>
                </property>
                <property name="wordWrap">
                 <bool>false</bool>
                </property>
               </widget>
              </item>
              <item row="1" column="1">
               <widget class="QDoubleSpinBox" name="m_EddyGradientStrength">
                <property name="toolTip">
                 <string>Maximum magnitude of eddy current induced magnetic field inhomogeneities (in mT).</string>
                </property>
                <property name="decimals">
                 <number>5</number>
                </property>
                <property name="maximum">
                 <double>1000.000000000000000</double>
                </property>
                <property name="singleStep">
                 <double>0.001000000000000</double>
                </property>
                <property name="value">
                 <double>0.005000000000000</double>
                </property>
               </widget>
              </item>
              <item row="0" column="1">
               <widget class="QLabel" name="m_DiffusionPropsMessage_2">
                <property name="styleSheet">
                 <string notr="true">color: rgb(255, 0, 0);</string>
                </property>
                <property name="text">
                 <string>Experimental!</string>
                </property>
               </widget>
              </item>
             </layout>
            </widget>
           </item>
           <item row="5" column="0">
            <widget class="Line" name="line_8">
             <property name="orientation">
              <enum>Qt::Horizontal</enum>
             </property>
            </widget>
           </item>
           <item row="2" column="0">
            <widget class="Line" name="line_9">
             <property name="orientation">
              <enum>Qt::Horizontal</enum>
             </property>
            </widget>
           </item>
          </layout>
         </widget>
        </item>
        <item row="2" column="0">
         <widget class="QCommandLinkButton" name="m_GenerateImageButton">
          <property name="enabled">
           <bool>true</bool>
          </property>
          <property name="toolTip">
           <string>&lt;html&gt;&lt;head/&gt;&lt;body&gt;&lt;p&gt;Start DWI generation from selected fiber bundle.&lt;/p&gt;&lt;p&gt;If no fiber bundle but an existing diffusion weighted image is selected, the enabled artifacts are added to this image.&lt;/p&gt;&lt;p&gt;If neither a fiber bundle nor a diffusion weighted image is selected, a grayscale image containing a simple gradient is generated.&lt;/p&gt;&lt;/body&gt;&lt;/html&gt;</string>
          </property>
          <property name="text">
           <string>Start Simulation</string>
          </property>
          <property name="icon">
           <iconset resource="../../resources/QmitkDiffusionImaging.qrc">
            <normaloff>:/QmitkDiffusionImaging/general_icons/right.ico</normaloff>:/QmitkDiffusionImaging/general_icons/right.ico</iconset>
          </property>
         </widget>
        </item>
        <item row="8" column="0">
         <widget class="QGroupBox" name="m_IntraAxonalGroupBox">
          <property name="title">
           <string>Intra-axonal Compartment</string>
          </property>
          <layout class="QGridLayout" name="gridLayout_13">
           <item row="2" column="0">
            <widget class="QmitkZeppelinModelParametersWidget" name="m_ZeppelinWidget1" native="true"/>
           </item>
           <item row="3" column="0">
            <widget class="QmitkTensorModelParametersWidget" name="m_TensorWidget1" native="true"/>
           </item>
           <item row="0" column="0">
            <widget class="QComboBox" name="m_Compartment1Box">
             <property name="toolTip">
              <string>Select signal model for intra-axonal compartment.</string>
             </property>
             <item>
              <property name="text">
               <string>Stick Model</string>
              </property>
             </item>
             <item>
              <property name="text">
               <string>Zeppelin Model</string>
              </property>
             </item>
             <item>
              <property name="text">
               <string>Tensor Model</string>
              </property>
             </item>
             <item>
              <property name="text">
               <string>Prototype Signal</string>
              </property>
             </item>
            </widget>
           </item>
           <item row="1" column="0">
            <widget class="QmitkStickModelParametersWidget" name="m_StickWidget1" native="true"/>
           </item>
           <item row="4" column="0">
            <widget class="QmitkPrototypeSignalParametersWidget" name="m_PrototypeWidget1" native="true"/>
           </item>
          </layout>
         </widget>
        </item>
       </layout>
      </widget>
     </widget>
    </item>
    <item row="2" column="0">
     <widget class="QCommandLinkButton" name="m_SaveParametersButton">
      <property name="text">
       <string>Save Parameters</string>
      </property>
      <property name="icon">
       <iconset resource="../../resources/QmitkDiffusionImaging.qrc">
        <normaloff>:/QmitkDiffusionImaging/general_icons/download.ico</normaloff>:/QmitkDiffusionImaging/general_icons/download.ico</iconset>
      </property>
     </widget>
    </item>
   </layout>
  </widget>
  <customwidgets>
   <customwidget>
    <class>QmitkDataStorageComboBox</class>
    <extends>QComboBox</extends>
    <header location="global">QmitkDataStorageComboBox.h</header>
   </customwidget>
   <customwidget>
    <class>QmitkTensorModelParametersWidget</class>
    <extends>QWidget</extends>
    <header location="global">QmitkTensorModelParametersWidget.h</header>
    <container>1</container>
   </customwidget>
   <customwidget>
    <class>QmitkStickModelParametersWidget</class>
    <extends>QWidget</extends>
    <header location="global">QmitkStickModelParametersWidget.h</header>
    <container>1</container>
   </customwidget>
   <customwidget>
    <class>QmitkZeppelinModelParametersWidget</class>
    <extends>QWidget</extends>
    <header location="global">QmitkZeppelinModelParametersWidget.h</header>
    <container>1</container>
   </customwidget>
   <customwidget>
    <class>QmitkBallModelParametersWidget</class>
    <extends>QWidget</extends>
    <header location="global">QmitkBallModelParametersWidget.h</header>
    <container>1</container>
   </customwidget>
   <customwidget>
    <class>QmitkAstrosticksModelParametersWidget</class>
    <extends>QWidget</extends>
    <header location="global">QmitkAstrosticksModelParametersWidget.h</header>
    <container>1</container>
   </customwidget>
   <customwidget>
    <class>QmitkDotModelParametersWidget</class>
    <extends>QWidget</extends>
    <header>QmitkDotModelParametersWidget.h</header>
    <container>1</container>
   </customwidget>
   <customwidget>
    <class>QmitkPrototypeSignalParametersWidget</class>
    <extends>QWidget</extends>
    <header>QmitkPrototypeSignalParametersWidget.h</header>
    <container>1</container>
   </customwidget>
   <customwidget>
    <class>QmitkDataStorageComboBoxWithSelectNone</class>
    <extends>QComboBox</extends>
    <header location="global">QmitkDataStorageComboBoxWithSelectNone.h</header>
   </customwidget>
  </customwidgets>
  <tabstops>
   <tabstop>m_CircleButton</tabstop>
   <tabstop>m_FlipButton</tabstop>
   <tabstop>m_RealTimeFibers</tabstop>
   <tabstop>m_AdvancedOptionsBox</tabstop>
   <tabstop>m_DistributionBox</tabstop>
   <tabstop>m_VarianceBox</tabstop>
   <tabstop>m_FiberDensityBox</tabstop>
   <tabstop>m_FiberSamplingBox</tabstop>
   <tabstop>m_TensionBox</tabstop>
   <tabstop>m_ContinuityBox</tabstop>
   <tabstop>m_BiasBox</tabstop>
   <tabstop>m_GenerateFibersButton</tabstop>
   <tabstop>m_ConstantRadiusBox</tabstop>
   <tabstop>m_AlignOnGrid</tabstop>
   <tabstop>m_XrotBox</tabstop>
   <tabstop>m_YrotBox</tabstop>
   <tabstop>m_ZrotBox</tabstop>
   <tabstop>m_XtransBox</tabstop>
   <tabstop>m_YtransBox</tabstop>
   <tabstop>m_ZtransBox</tabstop>
   <tabstop>m_XscaleBox</tabstop>
   <tabstop>m_YscaleBox</tabstop>
   <tabstop>m_ZscaleBox</tabstop>
   <tabstop>m_TransformBundlesButton</tabstop>
   <tabstop>m_CopyBundlesButton</tabstop>
   <tabstop>m_JoinBundlesButton</tabstop>
   <tabstop>m_IncludeFiducials</tabstop>
   <tabstop>m_GenerateImageButton</tabstop>
   <tabstop>m_SizeX</tabstop>
   <tabstop>m_SizeY</tabstop>
   <tabstop>m_SizeZ</tabstop>
   <tabstop>m_SpacingX</tabstop>
   <tabstop>m_SpacingY</tabstop>
   <tabstop>m_SpacingZ</tabstop>
   <tabstop>m_NumGradientsBox</tabstop>
   <tabstop>m_BvalueBox</tabstop>
   <tabstop>m_AdvancedOptionsBox_2</tabstop>
   <tabstop>m_SignalScaleBox</tabstop>
   <tabstop>m_TEbox</tabstop>
   <tabstop>m_LineReadoutTimeBox</tabstop>
   <tabstop>m_T2starBox</tabstop>
   <tabstop>m_FiberRadius</tabstop>
   <tabstop>m_RelaxationBox</tabstop>
   <tabstop>m_EnforcePureFiberVoxelsBox</tabstop>
   <tabstop>m_VolumeFractionsBox</tabstop>
   <tabstop>m_Compartment1Box</tabstop>
   <tabstop>m_Compartment2Box</tabstop>
   <tabstop>m_Compartment3Box</tabstop>
   <tabstop>m_Compartment4Box</tabstop>
   <tabstop>m_AddNoise</tabstop>
   <tabstop>m_NoiseLevel</tabstop>
   <tabstop>m_AddSpikes</tabstop>
   <tabstop>m_SpikeNumBox</tabstop>
   <tabstop>m_SpikeScaleBox</tabstop>
   <tabstop>m_AddGhosts</tabstop>
   <tabstop>m_kOffsetBox</tabstop>
   <tabstop>m_AddAliasing</tabstop>
   <tabstop>m_WrapBox</tabstop>
   <tabstop>m_AddDistortions</tabstop>
   <tabstop>m_FrequencyMapBox</tabstop>
   <tabstop>m_AddMotion</tabstop>
   <tabstop>m_RandomMotion</tabstop>
   <tabstop>m_MaxRotationBoxX</tabstop>
   <tabstop>m_MaxRotationBoxY</tabstop>
   <tabstop>m_MaxRotationBoxZ</tabstop>
   <tabstop>m_MaxTranslationBoxX</tabstop>
   <tabstop>m_MaxTranslationBoxY</tabstop>
   <tabstop>m_MaxTranslationBoxZ</tabstop>
   <tabstop>m_AddEddy</tabstop>
   <tabstop>m_EddyGradientStrength</tabstop>
   <tabstop>m_AddGibbsRinging</tabstop>
   <tabstop>m_SaveParametersButton</tabstop>
   <tabstop>m_LoadParametersButton</tabstop>
   <tabstop>tabWidget</tabstop>
  </tabstops>
  <resources>
   <include location="../../resources/QmitkDiffusionImaging.qrc"/>
  </resources>
  <connections/>
 </ui>
diff --git a/Plugins/org.mitk.gui.qt.diffusionimaging/src/internal/QmitkPreprocessingView.cpp b/Plugins/org.mitk.gui.qt.diffusionimaging/src/internal/QmitkPreprocessingView.cpp
index 17a6ff10c7..3819a7d615 100644
--- a/Plugins/org.mitk.gui.qt.diffusionimaging/src/internal/QmitkPreprocessingView.cpp
+++ b/Plugins/org.mitk.gui.qt.diffusionimaging/src/internal/QmitkPreprocessingView.cpp
@@ -1,1872 +1,2036 @@
 /*===================================================================
 
 The Medical Imaging Interaction Toolkit (MITK)
 
 Copyright (c) German Cancer Research Center,
 Division of Medical and Biological Informatics.
 All rights reserved.
 
 This software is distributed WITHOUT ANY WARRANTY; without
 even the implied warranty of MERCHANTABILITY or FITNESS FOR
 A PARTICULAR PURPOSE.
 
 See LICENSE.txt or http://www.mitk.org for details.
 
 ===================================================================*/
 
 //#define MBILOG_ENABLE_DEBUG
 
 #include "QmitkPreprocessingView.h"
 #include "mitkDiffusionImagingConfigure.h"
 
 // qt includes
 #include <QMessageBox>
 
 // itk includes
 #include "itkTimeProbe.h"
 #include "itkB0ImageExtractionImageFilter.h"
 #include "itkB0ImageExtractionToSeparateImageFilter.h"
 #include "itkBrainMaskExtractionImageFilter.h"
 #include "itkCastImageFilter.h"
 #include "itkVectorContainer.h"
 #include <itkElectrostaticRepulsionDiffusionGradientReductionFilter.h>
 #include <itkMergeDiffusionImagesFilter.h>
 #include <itkDwiGradientLengthCorrectionFilter.h>
 #include <itkDwiNormilzationFilter.h>
 
 // Multishell includes
 #include <itkRadialMultishellToSingleshellImageFilter.h>
 
 // Multishell Functors
 #include <itkADCAverageFunctor.h>
 #include <itkKurtosisFitFunctor.h>
 #include <itkBiExpFitFunctor.h>
 #include <itkADCFitFunctor.h>
 
 // mitk includes
 #include "QmitkDataStorageComboBox.h"
 #include "QmitkStdMultiWidget.h"
 #include "mitkProgressBar.h"
 #include "mitkStatusBar.h"
 #include "mitkNodePredicateDataType.h"
 #include "mitkProperties.h"
 #include "mitkVtkResliceInterpolationProperty.h"
 #include "mitkLookupTable.h"
 #include "mitkLookupTableProperty.h"
 #include "mitkTransferFunction.h"
 #include "mitkTransferFunctionProperty.h"
 #include "mitkDataNodeObject.h"
 #include "mitkOdfNormalizationMethodProperty.h"
 #include "mitkOdfScaleByProperty.h"
 #include <mitkPointSet.h>
 #include <itkAdcImageFilter.h>
 #include <itkBrainMaskExtractionImageFilter.h>
 #include <mitkImageCast.h>
 #include <mitkRotationOperation.h>
 #include <QTableWidgetItem>
 #include <QTableWidget>
 #include <mitkInteractionConst.h>
 #include <mitkImageAccessByItk.h>
 #include <itkResampleDwiImageFilter.h>
 #include <itkResampleImageFilter.h>
 #include <itkImageDuplicator.h>
 #include <itkMaskImageFilter.h>
 #include <mitkNodePredicateProperty.h>
 #include <mitkNodePredicateAnd.h>
 #include <mitkNodePredicateNot.h>
 #include <mitkNodePredicateOr.h>
 #include <itkCropImageFilter.h>
 #include <itkDiffusionTensor3DReconstructionImageFilter.h>
 #include <itkRemoveDwiChannelFilter.h>
 #include <itkExtractDwiChannelFilter.h>
 #include <mitkITKImageImport.h>
 #include <mitkBValueMapProperty.h>
 #include <mitkGradientDirectionsProperty.h>
 #include <mitkMeasurementFrameProperty.h>
 #include <itkImageDuplicator.h>
+#include <itkFlipImageFilter.h>
+#include <mitkITKImageImport.h>
 
 const std::string QmitkPreprocessingView::VIEW_ID =
         "org.mitk.views.preprocessing";
 
 #define DI_INFO MITK_INFO("DiffusionImaging")
 
 
 typedef float TTensorPixelType;
 
 
 QmitkPreprocessingView::QmitkPreprocessingView()
     : QmitkFunctionality(),
       m_Controls(NULL),
       m_MultiWidget(NULL)
 {
 }
 
 QmitkPreprocessingView::~QmitkPreprocessingView()
 {
 
 }
 
 void QmitkPreprocessingView::CreateQtPartControl(QWidget *parent)
 {
     if (!m_Controls)
     {
         // create GUI widgets
         m_Controls = new Ui::QmitkPreprocessingViewControls;
         m_Controls->setupUi(parent);
         this->CreateConnections();
 
 #if QT_VERSION < QT_VERSION_CHECK(5, 0, 0)
         m_Controls->m_MeasurementFrameTable->horizontalHeader()->setResizeMode(QHeaderView::Stretch);
         m_Controls->m_MeasurementFrameTable->verticalHeader()->setResizeMode(QHeaderView::Stretch);
         m_Controls->m_DirectionMatrixTable->horizontalHeader()->setResizeMode(QHeaderView::Stretch);
         m_Controls->m_DirectionMatrixTable->verticalHeader()->setResizeMode(QHeaderView::Stretch);
 #else
         m_Controls->m_MeasurementFrameTable->horizontalHeader()->setSectionResizeMode(QHeaderView::Stretch);
         m_Controls->m_MeasurementFrameTable->verticalHeader()->setSectionResizeMode(QHeaderView::Stretch);
         m_Controls->m_DirectionMatrixTable->horizontalHeader()->setSectionResizeMode(QHeaderView::Stretch);
         m_Controls->m_DirectionMatrixTable->verticalHeader()->setSectionResizeMode(QHeaderView::Stretch);
 #endif
     }
 }
 
 void QmitkPreprocessingView::StdMultiWidgetAvailable (QmitkStdMultiWidget &stdMultiWidget)
 {
     m_MultiWidget = &stdMultiWidget;
 }
 
 void QmitkPreprocessingView::StdMultiWidgetNotAvailable()
 {
     m_MultiWidget = NULL;
 }
 
 void QmitkPreprocessingView::CreateConnections()
 {
     if ( m_Controls )
     {
         m_Controls->m_NormalizationMaskBox->SetDataStorage(this->GetDataStorage());
+        m_Controls->m_SelctedImageComboBox->SetDataStorage(this->GetDataStorage());
+        m_Controls->m_MergeDwiBox->SetDataStorage(this->GetDataStorage());
+
         mitk::TNodePredicateDataType<mitk::Image>::Pointer isMitkImage = mitk::TNodePredicateDataType<mitk::Image>::New();
         mitk::NodePredicateDataType::Pointer isDwi = mitk::NodePredicateDataType::New("DiffusionImage");
         mitk::NodePredicateDataType::Pointer isDti = mitk::NodePredicateDataType::New("TensorImage");
         mitk::NodePredicateDataType::Pointer isQbi = mitk::NodePredicateDataType::New("QBallImage");
         mitk::NodePredicateOr::Pointer isDiffusionImage = mitk::NodePredicateOr::New(isDwi, isDti);
         isDiffusionImage = mitk::NodePredicateOr::New(isDiffusionImage, isQbi);
+
         mitk::NodePredicateNot::Pointer noDiffusionImage = mitk::NodePredicateNot::New(isDiffusionImage);
         mitk::NodePredicateAnd::Pointer finalPredicate = mitk::NodePredicateAnd::New(isMitkImage, noDiffusionImage);
         mitk::NodePredicateProperty::Pointer isBinaryPredicate = mitk::NodePredicateProperty::New("binary", mitk::BoolProperty::New(true));
         finalPredicate = mitk::NodePredicateAnd::New(finalPredicate, isBinaryPredicate);
         m_Controls->m_NormalizationMaskBox->SetPredicate(finalPredicate);
+        m_Controls->m_SelctedImageComboBox->SetPredicate(isMitkImage);
+        m_Controls->m_MergeDwiBox->SetPredicate(isMitkImage);
 
         m_Controls->m_ExtractBrainMask->setVisible(false);
         m_Controls->m_BrainMaskIterationsBox->setVisible(false);
         m_Controls->m_ResampleIntFrame->setVisible(false);
         connect( (QObject*)(m_Controls->m_ButtonAverageGradients), SIGNAL(clicked()), this, SLOT(AverageGradients()) );
         connect( (QObject*)(m_Controls->m_ButtonExtractB0), SIGNAL(clicked()), this, SLOT(ExtractB0()) );
         connect( (QObject*)(m_Controls->m_ModifyMeasurementFrame), SIGNAL(clicked()), this, SLOT(DoApplyMesurementFrame()) );
         connect( (QObject*)(m_Controls->m_ReduceGradientsButton), SIGNAL(clicked()), this, SLOT(DoReduceGradientDirections()) );
         connect( (QObject*)(m_Controls->m_ShowGradientsButton), SIGNAL(clicked()), this, SLOT(DoShowGradientDirections()) );
         connect( (QObject*)(m_Controls->m_MirrorGradientToHalfSphereButton), SIGNAL(clicked()), this, SLOT(DoHalfSphereGradientDirections()) );
         connect( (QObject*)(m_Controls->m_MergeDwisButton), SIGNAL(clicked()), this, SLOT(MergeDwis()) );
         connect( (QObject*)(m_Controls->m_ProjectSignalButton), SIGNAL(clicked()), this, SLOT(DoProjectSignal()) );
         connect( (QObject*)(m_Controls->m_B_ValueMap_Rounder_SpinBox), SIGNAL(valueChanged(int)), this, SLOT(UpdateDwiBValueMapRounder(int)));
         connect( (QObject*)(m_Controls->m_CreateLengthCorrectedDwi), SIGNAL(clicked()), this, SLOT(DoLengthCorrection()) );
         connect( (QObject*)(m_Controls->m_CalcAdcButton), SIGNAL(clicked()), this, SLOT(DoAdcCalculation()) );
         connect( (QObject*)(m_Controls->m_NormalizeImageValuesButton), SIGNAL(clicked()), this, SLOT(DoDwiNormalization()) );
         connect( (QObject*)(m_Controls->m_ModifyDirection), SIGNAL(clicked()), this, SLOT(DoApplyDirectionMatrix()) );
         connect( (QObject*)(m_Controls->m_ModifySpacingButton), SIGNAL(clicked()), this, SLOT(DoApplySpacing()) );
         connect( (QObject*)(m_Controls->m_ModifyOriginButton), SIGNAL(clicked()), this, SLOT(DoApplyOrigin()) );
         connect( (QObject*)(m_Controls->m_ResampleImageButton), SIGNAL(clicked()), this, SLOT(DoResampleImage()) );
         connect( (QObject*)(m_Controls->m_ResampleTypeBox), SIGNAL(currentIndexChanged(int)), this, SLOT(DoUpdateInterpolationGui(int)) );
         connect( (QObject*)(m_Controls->m_CropImageButton), SIGNAL(clicked()), this, SLOT(DoCropImage()) );
         connect( (QObject*)(m_Controls->m_RemoveGradientButton), SIGNAL(clicked()), this, SLOT(DoRemoveGradient()) );
         connect( (QObject*)(m_Controls->m_ExtractGradientButton), SIGNAL(clicked()), this, SLOT(DoExtractGradient()) );
-
+        connect( (QObject*)(m_Controls->m_FlipAxis), SIGNAL(clicked()), this, SLOT(DoFlipAxis()) );
+        connect( (QObject*)(m_Controls->m_SelctedImageComboBox), SIGNAL(OnSelectionChanged(const mitk::DataNode*)), this, SLOT(OnImageSelectionChanged()) );
 
         //        connect( (QObject*)(m_Controls->m_ExtractBrainMask), SIGNAL(clicked()), this, SLOT(DoExtractBrainMask()) );
     }
 }
 
+void QmitkPreprocessingView::DoFlipAxis()
+{
+    mitk::DataNode::Pointer node = m_Controls->m_SelctedImageComboBox->GetSelectedNode();
+    if (node.IsNull())
+        return;
+    mitk::Image::Pointer image = dynamic_cast<mitk::Image*>(node->GetData());
+
+    bool isDiffusionImage( mitk::DiffusionPropertyHelper::IsDiffusionWeightedImage(node) );
+
+    if (isDiffusionImage)
+    {
+        ItkDwiType::Pointer itkVectorImagePointer = ItkDwiType::New();
+        mitk::CastToItkImage(image, itkVectorImagePointer);
+
+        itk::FixedArray<bool, 3> flipAxes;
+        flipAxes[0] = m_Controls->m_FlipX->isChecked();
+        flipAxes[1] = m_Controls->m_FlipY->isChecked();
+        flipAxes[2] = m_Controls->m_FlipZ->isChecked();
+
+        itk::FlipImageFilter< ItkDwiType >::Pointer flipper = itk::FlipImageFilter< ItkDwiType >::New();
+        flipper->SetInput(itkVectorImagePointer);
+        flipper->SetFlipAxes(flipAxes);
+        flipper->Update();
+
+        mitk::GradientDirectionsProperty::GradientDirectionsContainerType::Pointer oldGradients = static_cast<mitk::GradientDirectionsProperty*>( image->GetProperty(mitk::DiffusionPropertyHelper::GRADIENTCONTAINERPROPERTYNAME.c_str()).GetPointer() )->GetGradientDirectionsContainer();
+        mitk::GradientDirectionsProperty::GradientDirectionsContainerType::Pointer newGradients = mitk::GradientDirectionsProperty::GradientDirectionsContainerType::New();
+
+        for (unsigned int i=0; i<oldGradients->Size(); i++)
+        {
+            mitk::GradientDirectionsProperty::GradientDirectionType g = oldGradients->GetElement(i);
+            mitk::GradientDirectionsProperty::GradientDirectionType newG = g;
+            if (flipAxes[0])
+                newG[0] *= -1;
+            if (flipAxes[1])
+                newG[1] *= -1;
+            if (flipAxes[2])
+                newG[2] *= -1;
+            newGradients->InsertElement(i, newG);
+        }
+
+        mitk::Image::Pointer newImage = mitk::GrabItkImageMemory( flipper->GetOutput() );
+        newImage->SetProperty( mitk::DiffusionPropertyHelper::GRADIENTCONTAINERPROPERTYNAME.c_str(), mitk::GradientDirectionsProperty::New( newGradients ) );
+        newImage->SetProperty( mitk::DiffusionPropertyHelper::REFERENCEBVALUEPROPERTYNAME.c_str(), mitk::FloatProperty::New( static_cast<mitk::FloatProperty*>(image->GetProperty(mitk::DiffusionPropertyHelper::REFERENCEBVALUEPROPERTYNAME.c_str()).GetPointer() )->GetValue() ) );
+        newImage->SetProperty( mitk::DiffusionPropertyHelper::MEASUREMENTFRAMEPROPERTYNAME.c_str(), mitk::MeasurementFrameProperty::New( static_cast<mitk::MeasurementFrameProperty*>(image->GetProperty(mitk::DiffusionPropertyHelper::MEASUREMENTFRAMEPROPERTYNAME.c_str()).GetPointer() )->GetMeasurementFrame() ) );
+        mitk::DiffusionPropertyHelper propertyHelper( newImage );
+        propertyHelper.InitializeImage();
+        newImage->GetGeometry()->SetOrigin(image->GetGeometry()->GetOrigin());
+
+        mitk::DataNode::Pointer imageNode = mitk::DataNode::New();
+        imageNode->SetData( newImage );
+        QString name = node->GetName().c_str();
+
+        imageNode->SetName((name+"_flipped").toStdString().c_str());
+        GetDefaultDataStorage()->Add(imageNode, node);
+
+        mitk::RenderingManager::GetInstance()->InitializeViews( imageNode->GetData()->GetTimeGeometry(), mitk::RenderingManager::REQUEST_UPDATE_ALL, true );
+        mitk::RenderingManager::GetInstance()->RequestUpdateAll();
+    }
+    else
+        AccessFixedDimensionByItk(image, TemplatedFlipAxis,3);
+}
+
+
+template < typename TPixel, unsigned int VImageDimension >
+void QmitkPreprocessingView::TemplatedFlipAxis(itk::Image<TPixel, VImageDimension>* itkImage)
+{
+    mitk::DataNode::Pointer node = m_Controls->m_SelctedImageComboBox->GetSelectedNode();
+    if (node.IsNull())
+        return;
+    mitk::Image::Pointer image = dynamic_cast<mitk::Image*>(node->GetData());
+
+    itk::FixedArray<bool, 3> flipAxes;
+    flipAxes[0] = m_Controls->m_FlipX->isChecked();
+    flipAxes[1] = m_Controls->m_FlipY->isChecked();
+    flipAxes[2] = m_Controls->m_FlipZ->isChecked();
+
+    typename itk::FlipImageFilter< itk::Image<TPixel, VImageDimension> >::Pointer flipper = itk::FlipImageFilter< itk::Image<TPixel, VImageDimension> >::New();
+    flipper->SetInput(itkImage);
+    flipper->SetFlipAxes(flipAxes);
+    flipper->Update();
+
+    mitk::Image::Pointer newImage = mitk::GrabItkImageMemory( flipper->GetOutput() );
+    newImage->GetGeometry()->SetOrigin(image->GetGeometry()->GetOrigin());
+
+    mitk::DataNode::Pointer imageNode = mitk::DataNode::New();
+    imageNode->SetData( newImage );
+    QString name = node->GetName().c_str();
+
+    imageNode->SetName((name+"_flipped").toStdString().c_str());
+    GetDefaultDataStorage()->Add(imageNode, node);
+
+    mitk::RenderingManager::GetInstance()->InitializeViews( imageNode->GetData()->GetTimeGeometry(), mitk::RenderingManager::REQUEST_UPDATE_ALL, true );
+    mitk::RenderingManager::GetInstance()->RequestUpdateAll();
+}
+
 void QmitkPreprocessingView::DoRemoveGradient()
 {
-    bool isDiffusionImage( mitk::DiffusionPropertyHelper::IsDiffusionWeightedImage( dynamic_cast<mitk::Image *>(m_SelectedImageNode->GetData())) );
+    mitk::DataNode::Pointer node = m_Controls->m_SelctedImageComboBox->GetSelectedNode();
+    if (node.IsNull())
+        return;
+    mitk::Image::Pointer image = dynamic_cast<mitk::Image*>(node->GetData());
+
+    bool isDiffusionImage( mitk::DiffusionPropertyHelper::IsDiffusionWeightedImage(image) );
     if ( !isDiffusionImage )
     {
         return;
     }
 
     std::vector< unsigned int > channelsToRemove; channelsToRemove.push_back(m_Controls->m_RemoveGradientBox->value());
 
     ItkDwiType::Pointer itkVectorImagePointer = ItkDwiType::New();
-    mitk::CastToItkImage(m_SelectedImage, itkVectorImagePointer);
+    mitk::CastToItkImage(image, itkVectorImagePointer);
 
     itk::RemoveDwiChannelFilter< short >::Pointer filter = itk::RemoveDwiChannelFilter< short >::New();
     filter->SetInput(itkVectorImagePointer);
     filter->SetChannelIndices(channelsToRemove);
-    filter->SetDirections( static_cast<mitk::GradientDirectionsProperty*>( m_SelectedImage->GetProperty(mitk::DiffusionPropertyHelper::GRADIENTCONTAINERPROPERTYNAME.c_str()).GetPointer() )->GetGradientDirectionsContainer() );
+    filter->SetDirections( static_cast<mitk::GradientDirectionsProperty*>( image->GetProperty(mitk::DiffusionPropertyHelper::GRADIENTCONTAINERPROPERTYNAME.c_str()).GetPointer() )->GetGradientDirectionsContainer() );
     filter->Update();
 
-    mitk::Image::Pointer image = mitk::GrabItkImageMemory( filter->GetOutput() );
-    image->SetProperty( mitk::DiffusionPropertyHelper::GRADIENTCONTAINERPROPERTYNAME.c_str(), mitk::GradientDirectionsProperty::New( filter->GetNewDirections() ) );
-    image->SetProperty( mitk::DiffusionPropertyHelper::REFERENCEBVALUEPROPERTYNAME.c_str(), mitk::FloatProperty::New( static_cast<mitk::FloatProperty*>(m_SelectedImage->GetProperty(mitk::DiffusionPropertyHelper::REFERENCEBVALUEPROPERTYNAME.c_str()).GetPointer() )->GetValue() ) );
-    image->SetProperty( mitk::DiffusionPropertyHelper::MEASUREMENTFRAMEPROPERTYNAME.c_str(), mitk::MeasurementFrameProperty::New( static_cast<mitk::MeasurementFrameProperty*>(m_SelectedImage->GetProperty(mitk::DiffusionPropertyHelper::MEASUREMENTFRAMEPROPERTYNAME.c_str()).GetPointer() )->GetMeasurementFrame() ) );
-    mitk::DiffusionPropertyHelper propertyHelper( image );
+    mitk::Image::Pointer newImage = mitk::GrabItkImageMemory( filter->GetOutput() );
+    newImage->SetProperty( mitk::DiffusionPropertyHelper::GRADIENTCONTAINERPROPERTYNAME.c_str(), mitk::GradientDirectionsProperty::New( filter->GetNewDirections() ) );
+    newImage->SetProperty( mitk::DiffusionPropertyHelper::REFERENCEBVALUEPROPERTYNAME.c_str(), mitk::FloatProperty::New( static_cast<mitk::FloatProperty*>(image->GetProperty(mitk::DiffusionPropertyHelper::REFERENCEBVALUEPROPERTYNAME.c_str()).GetPointer() )->GetValue() ) );
+    newImage->SetProperty( mitk::DiffusionPropertyHelper::MEASUREMENTFRAMEPROPERTYNAME.c_str(), mitk::MeasurementFrameProperty::New( static_cast<mitk::MeasurementFrameProperty*>(image->GetProperty(mitk::DiffusionPropertyHelper::MEASUREMENTFRAMEPROPERTYNAME.c_str()).GetPointer() )->GetMeasurementFrame() ) );
+    mitk::DiffusionPropertyHelper propertyHelper( newImage );
     propertyHelper.InitializeImage();
 
     mitk::DataNode::Pointer imageNode = mitk::DataNode::New();
-    imageNode->SetData( image );
-    QString name = m_SelectedDiffusionNodes.back()->GetName().c_str();
+    imageNode->SetData( newImage );
+    QString name = node->GetName().c_str();
 
     imageNode->SetName((name+"_removedgradients").toStdString().c_str());
-    GetDefaultDataStorage()->Add(imageNode, m_SelectedDiffusionNodes.back());
+    GetDefaultDataStorage()->Add(imageNode, node);
 
     mitk::RenderingManager::GetInstance()->InitializeViews( imageNode->GetData()->GetTimeGeometry(), mitk::RenderingManager::REQUEST_UPDATE_ALL, true );
     mitk::RenderingManager::GetInstance()->RequestUpdateAll();
 }
 
 void QmitkPreprocessingView::DoExtractGradient()
 {
-    bool isDiffusionImage( mitk::DiffusionPropertyHelper::IsDiffusionWeightedImage( dynamic_cast<mitk::Image *>(m_SelectedImageNode->GetData())) );
+    mitk::DataNode::Pointer node = m_Controls->m_SelctedImageComboBox->GetSelectedNode();
+    if (node.IsNull())
+        return;
+    mitk::Image::Pointer image = dynamic_cast<mitk::Image*>(node->GetData());
+
+    bool isDiffusionImage( mitk::DiffusionPropertyHelper::IsDiffusionWeightedImage(image) );
     if ( !isDiffusionImage )
     {
         return;
     }
 
     ItkDwiType::Pointer itkVectorImagePointer = ItkDwiType::New();
-    mitk::CastToItkImage(m_SelectedImage, itkVectorImagePointer);
+    mitk::CastToItkImage(image, itkVectorImagePointer);
 
     unsigned int channel = m_Controls->m_ExtractGradientBox->value();
     itk::ExtractDwiChannelFilter< short >::Pointer filter = itk::ExtractDwiChannelFilter< short >::New();
     filter->SetInput( itkVectorImagePointer);
     filter->SetChannelIndex(channel);
     filter->Update();
 
-    mitk::Image::Pointer mitkImage = mitk::Image::New();
-    mitkImage->InitializeByItk( filter->GetOutput() );
-    mitkImage->SetImportChannel( filter->GetOutput()->GetBufferPointer() );
+    mitk::Image::Pointer newImage = mitk::Image::New();
+    newImage->InitializeByItk( filter->GetOutput() );
+    newImage->SetImportChannel( filter->GetOutput()->GetBufferPointer() );
 
     mitk::DataNode::Pointer imageNode = mitk::DataNode::New();
-    imageNode->SetData( mitkImage );
-    QString name = m_SelectedDiffusionNodes.back()->GetName().c_str();
+    imageNode->SetData( newImage );
+    QString name = node->GetName().c_str();
     imageNode->SetName((name+"_direction-"+QString::number(channel)).toStdString().c_str());
-    GetDefaultDataStorage()->Add(imageNode, m_SelectedDiffusionNodes.back());
+    GetDefaultDataStorage()->Add(imageNode, node);
 
     mitk::RenderingManager::GetInstance()->InitializeViews(imageNode->GetData()->GetTimeGeometry(),mitk::RenderingManager::REQUEST_UPDATE_ALL, true);
 }
 
 void QmitkPreprocessingView::DoCropImage()
 {
-    bool isDiffusionImage( mitk::DiffusionPropertyHelper::IsDiffusionWeightedImage( dynamic_cast<mitk::Image *>(m_SelectedImageNode->GetData())) );
+    mitk::DataNode::Pointer node = m_Controls->m_SelctedImageComboBox->GetSelectedNode();
+    if (node.IsNull())
+        return;
+    mitk::Image::Pointer image = dynamic_cast<mitk::Image*>(node->GetData());
+
+    bool isDiffusionImage( mitk::DiffusionPropertyHelper::IsDiffusionWeightedImage(image) );
     if ( isDiffusionImage )
     {
         ItkDwiType::Pointer itkVectorImagePointer = ItkDwiType::New();
-        mitk::CastToItkImage(m_SelectedImage, itkVectorImagePointer);
+        mitk::CastToItkImage(image, itkVectorImagePointer);
 
         ItkDwiType::SizeType lower;
         ItkDwiType::SizeType upper;
         lower[0] = m_Controls->m_XstartBox->value();
         lower[1] = m_Controls->m_YstartBox->value();
         lower[2] = m_Controls->m_ZstartBox->value();
         upper[0] = m_Controls->m_XendBox->value();
         upper[1] = m_Controls->m_YendBox->value();
         upper[2] = m_Controls->m_ZendBox->value();
 
         itk::CropImageFilter< ItkDwiType, ItkDwiType >::Pointer cropper = itk::CropImageFilter< ItkDwiType, ItkDwiType >::New();
         cropper->SetLowerBoundaryCropSize(lower);
         cropper->SetUpperBoundaryCropSize(upper);
         cropper->SetInput( itkVectorImagePointer );
         cropper->Update();
 
         mitk::Image::Pointer image = mitk::GrabItkImageMemory( cropper->GetOutput() );
-        image->SetProperty( mitk::DiffusionPropertyHelper::GRADIENTCONTAINERPROPERTYNAME.c_str(), mitk::GradientDirectionsProperty::New( static_cast<mitk::GradientDirectionsProperty*>( m_SelectedImage->GetProperty(mitk::DiffusionPropertyHelper::GRADIENTCONTAINERPROPERTYNAME.c_str()).GetPointer() )->GetGradientDirectionsContainer() ) );
-        image->SetProperty( mitk::DiffusionPropertyHelper::REFERENCEBVALUEPROPERTYNAME.c_str(), mitk::FloatProperty::New( static_cast<mitk::FloatProperty*>(m_SelectedImage->GetProperty(mitk::DiffusionPropertyHelper::REFERENCEBVALUEPROPERTYNAME.c_str()).GetPointer() )->GetValue() ) );
-        image->SetProperty( mitk::DiffusionPropertyHelper::MEASUREMENTFRAMEPROPERTYNAME.c_str(), mitk::MeasurementFrameProperty::New( static_cast<mitk::MeasurementFrameProperty*>(m_SelectedImage->GetProperty(mitk::DiffusionPropertyHelper::MEASUREMENTFRAMEPROPERTYNAME.c_str()).GetPointer() )->GetMeasurementFrame() ) );
+        image->SetProperty( mitk::DiffusionPropertyHelper::GRADIENTCONTAINERPROPERTYNAME.c_str(), mitk::GradientDirectionsProperty::New( static_cast<mitk::GradientDirectionsProperty*>( image->GetProperty(mitk::DiffusionPropertyHelper::GRADIENTCONTAINERPROPERTYNAME.c_str()).GetPointer() )->GetGradientDirectionsContainer() ) );
+        image->SetProperty( mitk::DiffusionPropertyHelper::REFERENCEBVALUEPROPERTYNAME.c_str(), mitk::FloatProperty::New( static_cast<mitk::FloatProperty*>(image->GetProperty(mitk::DiffusionPropertyHelper::REFERENCEBVALUEPROPERTYNAME.c_str()).GetPointer() )->GetValue() ) );
+        image->SetProperty( mitk::DiffusionPropertyHelper::MEASUREMENTFRAMEPROPERTYNAME.c_str(), mitk::MeasurementFrameProperty::New( static_cast<mitk::MeasurementFrameProperty*>(image->GetProperty(mitk::DiffusionPropertyHelper::MEASUREMENTFRAMEPROPERTYNAME.c_str()).GetPointer() )->GetMeasurementFrame() ) );
         mitk::DiffusionPropertyHelper propertyHelper( image );
         propertyHelper.InitializeImage();
 
         mitk::DataNode::Pointer imageNode = mitk::DataNode::New();
         imageNode->SetData( image );
-        QString name = m_SelectedDiffusionNodes.back()->GetName().c_str();
+        QString name = node->GetName().c_str();
         imageNode->SetName((name+"_cropped").toStdString().c_str());
-        GetDefaultDataStorage()->Add(imageNode, m_SelectedDiffusionNodes.back());
+        GetDefaultDataStorage()->Add(imageNode, node);
         mitk::RenderingManager::GetInstance()->InitializeViews( imageNode->GetData()->GetTimeGeometry(), mitk::RenderingManager::REQUEST_UPDATE_ALL, true );
         mitk::RenderingManager::GetInstance()->RequestUpdateAll();
 
         mitk::RenderingManager::GetInstance()->InitializeViews( imageNode->GetData()->GetTimeGeometry(), mitk::RenderingManager::REQUEST_UPDATE_ALL, true );
         mitk::RenderingManager::GetInstance()->RequestUpdateAll();
     }
-    else if(m_SelectedImage.IsNotNull())
+    else
     {
-        AccessFixedDimensionByItk(m_SelectedImage, TemplatedCropImage,3);
+        AccessFixedDimensionByItk(image, TemplatedCropImage,3);
     }
 }
 
 template < typename TPixel, unsigned int VImageDimension >
 void QmitkPreprocessingView::TemplatedCropImage( itk::Image<TPixel, VImageDimension>* itkImage)
 {
+    mitk::DataNode::Pointer node = m_Controls->m_SelctedImageComboBox->GetSelectedNode();
+    if (node.IsNull())
+        return;
+
     ItkDwiType::SizeType lower;
     ItkDwiType::SizeType upper;
     lower[0] = m_Controls->m_XstartBox->value();
     lower[1] = m_Controls->m_YstartBox->value();
     lower[2] = m_Controls->m_ZstartBox->value();
     upper[0] = m_Controls->m_XendBox->value();
     upper[1] = m_Controls->m_YendBox->value();
     upper[2] = m_Controls->m_ZendBox->value();
 
     typedef itk::Image<TPixel, VImageDimension> ImageType;
     typename itk::CropImageFilter< ImageType, ImageType >::Pointer cropper = itk::CropImageFilter< ImageType, ImageType >::New();
     cropper->SetLowerBoundaryCropSize(lower);
     cropper->SetUpperBoundaryCropSize(upper);
     cropper->SetInput(itkImage);
     cropper->Update();
 
+    typename ImageType::Pointer itkOutImage = cropper->GetOutput();
+    itk::Point<double,3> origin = itkOutImage->GetOrigin();
+    origin[0] += lower[0]*itkOutImage->GetSpacing()[0];
+    origin[1] += lower[1]*itkOutImage->GetSpacing()[1];
+    origin[2] += lower[2]*itkOutImage->GetSpacing()[2];
+    itkOutImage->SetOrigin(origin);
     mitk::Image::Pointer image = mitk::Image::New();
-    image->InitializeByItk( cropper->GetOutput() );
-    image->SetVolume( cropper->GetOutput()->GetBufferPointer() );
+    image->InitializeByItk( itkOutImage.GetPointer() );
+    image->SetVolume( itkOutImage->GetBufferPointer() );
     mitk::DataNode::Pointer imageNode = mitk::DataNode::New();
     imageNode->SetData( image );
-    QString name = m_SelectedImageNode->GetName().c_str();
+    QString name = node->GetName().c_str();
 
     imageNode->SetName((name+"_cropped").toStdString().c_str());
-    GetDefaultDataStorage()->Add(imageNode, m_SelectedImageNode);
+    GetDefaultDataStorage()->Add(imageNode, node);
 
     mitk::RenderingManager::GetInstance()->InitializeViews( imageNode->GetData()->GetTimeGeometry(), mitk::RenderingManager::REQUEST_UPDATE_ALL, true );
     mitk::RenderingManager::GetInstance()->RequestUpdateAll();
 }
 
 void QmitkPreprocessingView::DoApplySpacing()
 {
-    bool isDiffusionImage( mitk::DiffusionPropertyHelper::IsDiffusionWeightedImage( m_SelectedImageNode) );
+    mitk::DataNode::Pointer node = m_Controls->m_SelctedImageComboBox->GetSelectedNode();
+    if (node.IsNull())
+        return;
+    mitk::Image::Pointer image = dynamic_cast<mitk::Image*>(node->GetData());
+
+    bool isDiffusionImage( mitk::DiffusionPropertyHelper::IsDiffusionWeightedImage(image) );
     if ( isDiffusionImage )
     {
         mitk::Vector3D spacing;
         spacing[0] = m_Controls->m_HeaderSpacingX->value();
         spacing[1] = m_Controls->m_HeaderSpacingY->value();
         spacing[2] = m_Controls->m_HeaderSpacingZ->value();
 
-        mitk::Image::Pointer image = m_SelectedImage->Clone();
-        image->GetGeometry()->SetSpacing( spacing );
-        mitk::DiffusionPropertyHelper propertyHelper( image );
+        mitk::Image::Pointer newImage = image->Clone();
+        newImage->GetGeometry()->SetSpacing( spacing );
+        mitk::DiffusionPropertyHelper propertyHelper( newImage );
         propertyHelper.InitializeImage();
 
         mitk::DataNode::Pointer imageNode = mitk::DataNode::New();
-        imageNode->SetData( image );
-        QString name = m_SelectedDiffusionNodes.back()->GetName().c_str();
+        imageNode->SetData( newImage );
+        QString name = node->GetName().c_str();
         imageNode->SetName((name+"_newspacing").toStdString().c_str());
-        GetDefaultDataStorage()->Add(imageNode, m_SelectedDiffusionNodes.back());
+        GetDefaultDataStorage()->Add(imageNode, node);
         mitk::RenderingManager::GetInstance()->InitializeViews( imageNode->GetData()->GetTimeGeometry(), mitk::RenderingManager::REQUEST_UPDATE_ALL, true );
         mitk::RenderingManager::GetInstance()->RequestUpdateAll();
     }
-    else if(m_SelectedImage.IsNotNull())
+    else
     {
-        AccessFixedDimensionByItk(m_SelectedImage, TemplatedSetImageSpacing,3);
+        AccessFixedDimensionByItk(image, TemplatedSetImageSpacing,3);
     }
 }
 
 template < typename TPixel, unsigned int VImageDimension >
 void QmitkPreprocessingView::TemplatedSetImageSpacing( itk::Image<TPixel, VImageDimension>* itkImage)
 {
+    mitk::DataNode::Pointer node = m_Controls->m_SelctedImageComboBox->GetSelectedNode();
+    if (node.IsNull())
+        return;
+
     mitk::Vector3D spacing;
     spacing[0] = m_Controls->m_HeaderSpacingX->value();
     spacing[1] = m_Controls->m_HeaderSpacingY->value();
     spacing[2] = m_Controls->m_HeaderSpacingZ->value();
 
     typedef itk::ImageDuplicator< itk::Image<TPixel, VImageDimension> > DuplicateFilterType;
     typename DuplicateFilterType::Pointer duplicator = DuplicateFilterType::New();
     duplicator->SetInputImage( itkImage );
     duplicator->Update();
     typename itk::Image<TPixel, VImageDimension>::Pointer newImage = duplicator->GetOutput();
     newImage->SetSpacing(spacing);
 
     mitk::Image::Pointer image = mitk::Image::New();
     image->InitializeByItk( newImage.GetPointer() );
     image->SetVolume( newImage->GetBufferPointer() );
     mitk::DataNode::Pointer imageNode = mitk::DataNode::New();
     imageNode->SetData( image );
-    QString name = m_SelectedImageNode->GetName().c_str();
+    QString name = node->GetName().c_str();
 
     imageNode->SetName((name+"_newspacing").toStdString().c_str());
-    GetDefaultDataStorage()->Add(imageNode, m_SelectedImageNode);
+    GetDefaultDataStorage()->Add(imageNode, node);
     mitk::RenderingManager::GetInstance()->InitializeViews( imageNode->GetData()->GetTimeGeometry(), mitk::RenderingManager::REQUEST_UPDATE_ALL, true );
     mitk::RenderingManager::GetInstance()->RequestUpdateAll();
 }
 
 void QmitkPreprocessingView::DoApplyOrigin()
 {
-    bool isDiffusionImage( mitk::DiffusionPropertyHelper::IsDiffusionWeightedImage( dynamic_cast<mitk::Image *>(m_SelectedImageNode->GetData())) );
+    mitk::DataNode::Pointer node = m_Controls->m_SelctedImageComboBox->GetSelectedNode();
+    if (node.IsNull())
+        return;
+    mitk::Image::Pointer image = dynamic_cast<mitk::Image*>(node->GetData());
+
+    bool isDiffusionImage( mitk::DiffusionPropertyHelper::IsDiffusionWeightedImage(image));
     if ( isDiffusionImage )
     {
         mitk::Vector3D origin;
         origin[0] = m_Controls->m_HeaderOriginX->value();
         origin[1] = m_Controls->m_HeaderOriginY->value();
         origin[2] = m_Controls->m_HeaderOriginZ->value();
 
-        mitk::Image::Pointer image = m_SelectedImage->Clone();
+        mitk::Image::Pointer newImage = image->Clone();
 
-        image->GetGeometry()->SetOrigin( origin );
-        mitk::DiffusionPropertyHelper propertyHelper( image );
+        newImage->GetGeometry()->SetOrigin( origin );
+        mitk::DiffusionPropertyHelper propertyHelper( newImage );
         propertyHelper.InitializeImage();
 
         mitk::DataNode::Pointer imageNode = mitk::DataNode::New();
-        imageNode->SetData( image );
-        QString name = m_SelectedDiffusionNodes.back()->GetName().c_str();
+        imageNode->SetData( newImage );
+        QString name = node->GetName().c_str();
         imageNode->SetName((name+"_neworigin").toStdString().c_str());
-        GetDefaultDataStorage()->Add(imageNode, m_SelectedDiffusionNodes.back());
+        GetDefaultDataStorage()->Add(imageNode, node);
         mitk::RenderingManager::GetInstance()->InitializeViews( imageNode->GetData()->GetTimeGeometry(), mitk::RenderingManager::REQUEST_UPDATE_ALL, true );
         mitk::RenderingManager::GetInstance()->RequestUpdateAll();
     }
-    else if(m_SelectedImage.IsNotNull())
+    else
     {
-        AccessFixedDimensionByItk(m_SelectedImage, TemplatedSetImageOrigin,3);
+        AccessFixedDimensionByItk(image, TemplatedSetImageOrigin,3);
     }
 }
 
 template < typename TPixel, unsigned int VImageDimension >
 void QmitkPreprocessingView::TemplatedSetImageOrigin( itk::Image<TPixel, VImageDimension>* itkImage)
 {
+    mitk::DataNode::Pointer node = m_Controls->m_SelctedImageComboBox->GetSelectedNode();
+    if (node.IsNull())
+        return;
+
     mitk::Vector3D origin;
     origin[0] = m_Controls->m_HeaderOriginX->value();
     origin[1] = m_Controls->m_HeaderOriginY->value();
     origin[2] = m_Controls->m_HeaderOriginZ->value();
 
     typedef itk::ImageDuplicator< itk::Image<TPixel, VImageDimension> > DuplicateFilterType;
     typename DuplicateFilterType::Pointer duplicator = DuplicateFilterType::New();
     duplicator->SetInputImage( itkImage );
     duplicator->Update();
     typename itk::Image<TPixel, VImageDimension>::Pointer newImage = duplicator->GetOutput();
     newImage->SetOrigin(origin);
 
     mitk::Image::Pointer image = mitk::Image::New();
     image->InitializeByItk( newImage.GetPointer() );
     image->SetVolume( newImage->GetBufferPointer() );
     mitk::DataNode::Pointer imageNode = mitk::DataNode::New();
     imageNode->SetData( image );
-    QString name = m_SelectedImageNode->GetName().c_str();
+    QString name = node->GetName().c_str();
 
     imageNode->SetName((name+"_neworigin").toStdString().c_str());
-    GetDefaultDataStorage()->Add(imageNode, m_SelectedImageNode);
+    GetDefaultDataStorage()->Add(imageNode, node);
     mitk::RenderingManager::GetInstance()->InitializeViews( imageNode->GetData()->GetTimeGeometry(), mitk::RenderingManager::REQUEST_UPDATE_ALL, true );
     mitk::RenderingManager::GetInstance()->RequestUpdateAll();
 }
 
 void QmitkPreprocessingView::DoUpdateInterpolationGui(int i)
 {
+    mitk::DataNode::Pointer node = m_Controls->m_SelctedImageComboBox->GetSelectedNode();
+    if (node.IsNull())
+        return;
+    mitk::Image::Pointer image = dynamic_cast<mitk::Image*>(node->GetData());
+
     switch (i)
     {
     case 0:
     {
         m_Controls->m_ResampleIntFrame->setVisible(false);
         m_Controls->m_ResampleDoubleFrame->setVisible(true);
         break;
     }
     case 1:
     {
         m_Controls->m_ResampleIntFrame->setVisible(false);
         m_Controls->m_ResampleDoubleFrame->setVisible(true);
 
-        if (m_SelectedImage.IsNotNull())
-        {
-            mitk::BaseGeometry* geom = m_SelectedImage->GetGeometry();
-            m_Controls->m_ResampleDoubleX->setValue(geom->GetSpacing()[0]);
-            m_Controls->m_ResampleDoubleY->setValue(geom->GetSpacing()[1]);
-            m_Controls->m_ResampleDoubleZ->setValue(geom->GetSpacing()[2]);
-        }
+        mitk::BaseGeometry* geom = image->GetGeometry();
+        m_Controls->m_ResampleDoubleX->setValue(geom->GetSpacing()[0]);
+        m_Controls->m_ResampleDoubleY->setValue(geom->GetSpacing()[1]);
+        m_Controls->m_ResampleDoubleZ->setValue(geom->GetSpacing()[2]);
         break;
     }
     case 2:
     {
         m_Controls->m_ResampleIntFrame->setVisible(true);
         m_Controls->m_ResampleDoubleFrame->setVisible(false);
 
-        if (m_SelectedImage.IsNotNull())
-        {
-            mitk::BaseGeometry* geom = m_SelectedImage->GetGeometry();
-            m_Controls->m_ResampleIntX->setValue(geom->GetExtent(0));
-            m_Controls->m_ResampleIntY->setValue(geom->GetExtent(1));
-            m_Controls->m_ResampleIntZ->setValue(geom->GetExtent(2));
-        }
+        mitk::BaseGeometry* geom = image->GetGeometry();
+        m_Controls->m_ResampleIntX->setValue(geom->GetExtent(0));
+        m_Controls->m_ResampleIntY->setValue(geom->GetExtent(1));
+        m_Controls->m_ResampleIntZ->setValue(geom->GetExtent(2));
         break;
     }
     default:
     {
         m_Controls->m_ResampleIntFrame->setVisible(false);
         m_Controls->m_ResampleDoubleFrame->setVisible(true);
     }
     }
 }
 
 void QmitkPreprocessingView::DoExtractBrainMask()
 {
-    //    if (m_SelectedImage.IsNull())
+    //    if (image.IsNull())
     //        return;
 
     //    typedef itk::Image<unsigned short, 3> ShortImageType;
     //    ShortImageType::Pointer itkImage = ShortImageType::New();
-    //    mitk::CastToItkImage(m_SelectedImage, itkImage);
+    //    mitk::CastToItkImage(image, itkImage);
 
     //    typedef itk::BrainMaskExtractionImageFilter< unsigned char > FilterType;
     //    FilterType::Pointer filter = FilterType::New();
     //    filter->SetInput(itkImage);
     //    filter->SetMaxNumIterations(m_Controls->m_BrainMaskIterationsBox->value());
     //    filter->Update();
 
     //    mitk::Image::Pointer image = mitk::Image::New();
     //    image->InitializeByItk( filter->GetOutput() );
     //    image->SetVolume( filter->GetOutput()->GetBufferPointer() );
     //    mitk::DataNode::Pointer imageNode = mitk::DataNode::New();
     //    imageNode->SetData( image );
     //    imageNode->SetName("BRAINMASK");
     //    GetDefaultDataStorage()->Add(imageNode);
 }
 
 void QmitkPreprocessingView::DoResampleImage()
 {
-    bool isDiffusionImage( mitk::DiffusionPropertyHelper::IsDiffusionWeightedImage( dynamic_cast<mitk::Image *>(m_SelectedImageNode->GetData())) );
+    mitk::DataNode::Pointer node = m_Controls->m_SelctedImageComboBox->GetSelectedNode();
+    if (node.IsNull())
+        return;
+    mitk::Image::Pointer image = dynamic_cast<mitk::Image*>(node->GetData());
+
+    bool isDiffusionImage( mitk::DiffusionPropertyHelper::IsDiffusionWeightedImage(image) );
     if ( isDiffusionImage )
     {
         ItkDwiType::Pointer itkVectorImagePointer = ItkDwiType::New();
-        mitk::CastToItkImage(m_SelectedImage, itkVectorImagePointer);
+        mitk::CastToItkImage(image, itkVectorImagePointer);
 
         typedef itk::ResampleDwiImageFilter< short > ResampleFilter;
         ResampleFilter::Pointer resampler = ResampleFilter::New();
         resampler->SetInput( itkVectorImagePointer );
 
         switch (m_Controls->m_ResampleTypeBox->currentIndex())
         {
         case 0:
         {
             itk::Vector< double, 3 > samplingFactor;
             samplingFactor[0] = m_Controls->m_ResampleDoubleX->value();
             samplingFactor[1] = m_Controls->m_ResampleDoubleY->value();
             samplingFactor[2] = m_Controls->m_ResampleDoubleZ->value();
             resampler->SetSamplingFactor(samplingFactor);
             break;
         }
         case 1:
         {
             itk::Vector< double, 3 > newSpacing;
             newSpacing[0] = m_Controls->m_ResampleDoubleX->value();
             newSpacing[1] = m_Controls->m_ResampleDoubleY->value();
             newSpacing[2] = m_Controls->m_ResampleDoubleZ->value();
             resampler->SetNewSpacing(newSpacing);
             break;
         }
         case 2:
         {
             itk::ImageRegion<3> newRegion;
             newRegion.SetSize(0, m_Controls->m_ResampleIntX->value());
             newRegion.SetSize(1, m_Controls->m_ResampleIntY->value());
             newRegion.SetSize(2, m_Controls->m_ResampleIntZ->value());
             resampler->SetNewImageSize(newRegion);
             break;
         }
         default:
         {
             MITK_WARN << "Unknown resampling parameters!";
             return;
         }
         }
 
         QString outAdd;
         switch (m_Controls->m_InterpolatorBox->currentIndex())
         {
         case 0:
         {
             resampler->SetInterpolation(ResampleFilter::Interpolate_NearestNeighbour);
             outAdd = "NearestNeighbour";
             break;
         }
         case 1:
         {
             resampler->SetInterpolation(ResampleFilter::Interpolate_Linear);
             outAdd = "Linear";
             break;
         }
         case 2:
         {
             resampler->SetInterpolation(ResampleFilter::Interpolate_BSpline);
             outAdd = "BSpline";
             break;
         }
         case 3:
         {
             resampler->SetInterpolation(ResampleFilter::Interpolate_WindowedSinc);
             outAdd = "WindowedSinc";
             break;
         }
         default:
         {
             resampler->SetInterpolation(ResampleFilter::Interpolate_NearestNeighbour);
             outAdd = "NearestNeighbour";
         }
         }
 
         resampler->Update();
 
-        mitk::Image::Pointer image = mitk::GrabItkImageMemory( resampler->GetOutput() );
-        image->SetProperty( mitk::DiffusionPropertyHelper::GRADIENTCONTAINERPROPERTYNAME.c_str(), mitk::GradientDirectionsProperty::New( static_cast<mitk::GradientDirectionsProperty*>( m_SelectedImage->GetProperty(mitk::DiffusionPropertyHelper::GRADIENTCONTAINERPROPERTYNAME.c_str()).GetPointer() )->GetGradientDirectionsContainer() ) );
-        image->SetProperty( mitk::DiffusionPropertyHelper::REFERENCEBVALUEPROPERTYNAME.c_str(), mitk::FloatProperty::New( static_cast<mitk::FloatProperty*>(m_SelectedImage->GetProperty(mitk::DiffusionPropertyHelper::REFERENCEBVALUEPROPERTYNAME.c_str()).GetPointer() )->GetValue() ) );
-        image->SetProperty( mitk::DiffusionPropertyHelper::MEASUREMENTFRAMEPROPERTYNAME.c_str(), mitk::MeasurementFrameProperty::New( static_cast<mitk::MeasurementFrameProperty*>(m_SelectedImage->GetProperty(mitk::DiffusionPropertyHelper::MEASUREMENTFRAMEPROPERTYNAME.c_str()).GetPointer() )->GetMeasurementFrame() ) );
-        mitk::DiffusionPropertyHelper propertyHelper( image );
+        mitk::Image::Pointer newImage = mitk::GrabItkImageMemory( resampler->GetOutput() );
+        newImage->SetProperty( mitk::DiffusionPropertyHelper::GRADIENTCONTAINERPROPERTYNAME.c_str(), mitk::GradientDirectionsProperty::New( static_cast<mitk::GradientDirectionsProperty*>( image->GetProperty(mitk::DiffusionPropertyHelper::GRADIENTCONTAINERPROPERTYNAME.c_str()).GetPointer() )->GetGradientDirectionsContainer() ) );
+        newImage->SetProperty( mitk::DiffusionPropertyHelper::REFERENCEBVALUEPROPERTYNAME.c_str(), mitk::FloatProperty::New( static_cast<mitk::FloatProperty*>(image->GetProperty(mitk::DiffusionPropertyHelper::REFERENCEBVALUEPROPERTYNAME.c_str()).GetPointer() )->GetValue() ) );
+        newImage->SetProperty( mitk::DiffusionPropertyHelper::MEASUREMENTFRAMEPROPERTYNAME.c_str(), mitk::MeasurementFrameProperty::New( static_cast<mitk::MeasurementFrameProperty*>(image->GetProperty(mitk::DiffusionPropertyHelper::MEASUREMENTFRAMEPROPERTYNAME.c_str()).GetPointer() )->GetMeasurementFrame() ) );
+        mitk::DiffusionPropertyHelper propertyHelper( newImage );
         propertyHelper.InitializeImage();
 
         mitk::DataNode::Pointer imageNode = mitk::DataNode::New();
-        imageNode->SetData( image );
-        QString name = m_SelectedDiffusionNodes.back()->GetName().c_str();
+        imageNode->SetData( newImage );
+        QString name = node->GetName().c_str();
 
         imageNode->SetName((name+"_resampled_"+outAdd).toStdString().c_str());
-        GetDefaultDataStorage()->Add(imageNode, m_SelectedDiffusionNodes.back());
+        imageNode->SetVisibility(false);
+        GetDefaultDataStorage()->Add(imageNode, node);
     }
-    else if (m_SelectedImage.IsNotNull())
+    else
     {
-        AccessFixedDimensionByItk(m_SelectedImage, TemplatedResampleImage,3);
+        AccessFixedDimensionByItk(image, TemplatedResampleImage,3);
     }
 }
 
 
 template < typename TPixel, unsigned int VImageDimension >
 void QmitkPreprocessingView::TemplatedResampleImage( itk::Image<TPixel, VImageDimension>* itkImage)
 {
+    mitk::DataNode::Pointer node = m_Controls->m_SelctedImageComboBox->GetSelectedNode();
+    if (node.IsNull())
+        return;
+
     itk::Vector< double, 3 > newSpacing;
     itk::ImageRegion<3>   newRegion;
 
     switch (m_Controls->m_ResampleTypeBox->currentIndex())
     {
     case 0:
     {
         itk::Vector< double, 3 > sampling;
         sampling[0] = m_Controls->m_ResampleDoubleX->value();
         sampling[1] = m_Controls->m_ResampleDoubleY->value();
         sampling[2] = m_Controls->m_ResampleDoubleZ->value();
 
         newSpacing = itkImage->GetSpacing();
         newSpacing[0] /= sampling[0];
         newSpacing[1] /= sampling[1];
         newSpacing[2] /= sampling[2];
         newRegion = itkImage->GetLargestPossibleRegion();
         newRegion.SetSize(0, newRegion.GetSize(0)*sampling[0]);
         newRegion.SetSize(1, newRegion.GetSize(1)*sampling[1]);
         newRegion.SetSize(2, newRegion.GetSize(2)*sampling[2]);
 
         break;
     }
     case 1:
     {
         newSpacing[0] = m_Controls->m_ResampleDoubleX->value();
         newSpacing[1] = m_Controls->m_ResampleDoubleY->value();
         newSpacing[2] = m_Controls->m_ResampleDoubleZ->value();
 
         itk::Vector< double, 3 > oldSpacing = itkImage->GetSpacing();
         itk::Vector< double, 3 > sampling;
         sampling[0] = oldSpacing[0]/newSpacing[0];
         sampling[1] = oldSpacing[1]/newSpacing[1];
         sampling[2] = oldSpacing[2]/newSpacing[2];
         newRegion = itkImage->GetLargestPossibleRegion();
         newRegion.SetSize(0, newRegion.GetSize(0)*sampling[0]);
         newRegion.SetSize(1, newRegion.GetSize(1)*sampling[1]);
         newRegion.SetSize(2, newRegion.GetSize(2)*sampling[2]);
         break;
     }
     case 2:
     {
         newRegion.SetSize(0, m_Controls->m_ResampleIntX->value());
         newRegion.SetSize(1, m_Controls->m_ResampleIntY->value());
         newRegion.SetSize(2, m_Controls->m_ResampleIntZ->value());
 
         itk::ImageRegion<3> oldRegion = itkImage->GetLargestPossibleRegion();
         itk::Vector< double, 3 > sampling;
         sampling[0] = (double)newRegion.GetSize(0)/oldRegion.GetSize(0);
         sampling[1] = (double)newRegion.GetSize(1)/oldRegion.GetSize(1);
         sampling[2] = (double)newRegion.GetSize(2)/oldRegion.GetSize(2);
 
         newSpacing = itkImage->GetSpacing();
         newSpacing[0] /= sampling[0];
         newSpacing[1] /= sampling[1];
         newSpacing[2] /= sampling[2];
         break;
     }
     default:
     {
         MITK_WARN << "Unknown resampling parameters!";
         return;
     }
     }
 
     itk::Point<double,3> origin = itkImage->GetOrigin();
     origin[0] -= itkImage->GetSpacing()[0]/2;
     origin[1] -= itkImage->GetSpacing()[1]/2;
     origin[2] -= itkImage->GetSpacing()[2]/2;
     origin[0] += newSpacing[0]/2;
     origin[1] += newSpacing[1]/2;
     origin[2] += newSpacing[2]/2;
 
     typedef itk::Image<TPixel, VImageDimension> ImageType;
     typename ImageType::Pointer outImage = ImageType::New();
     outImage->SetSpacing( newSpacing );
     outImage->SetOrigin( origin );
     outImage->SetDirection( itkImage->GetDirection() );
     outImage->SetLargestPossibleRegion( newRegion );
     outImage->SetBufferedRegion( newRegion );
     outImage->SetRequestedRegion( newRegion );
     outImage->Allocate();
 
     typedef itk::ResampleImageFilter<ImageType, ImageType> ResampleFilter;
     typename ResampleFilter::Pointer resampler = ResampleFilter::New();
     resampler->SetInput(itkImage);
     resampler->SetOutputParametersFromImage(outImage);
 
     QString outAdd;
     switch (m_Controls->m_InterpolatorBox->currentIndex())
     {
     case 0:
     {
         typename itk::NearestNeighborInterpolateImageFunction<ImageType>::Pointer interp = itk::NearestNeighborInterpolateImageFunction<ImageType>::New();
         resampler->SetInterpolator(interp);
         outAdd = "NearestNeighbour";
         break;
     }
     case 1:
     {
         typename itk::LinearInterpolateImageFunction<ImageType>::Pointer interp = itk::LinearInterpolateImageFunction<ImageType>::New();
         resampler->SetInterpolator(interp);
         outAdd = "Linear";
         break;
     }
     case 2:
     {
         typename itk::BSplineInterpolateImageFunction<ImageType>::Pointer interp = itk::BSplineInterpolateImageFunction<ImageType>::New();
         resampler->SetInterpolator(interp);
         outAdd = "BSpline";
         break;
     }
     case 3:
     {
         typename itk::WindowedSincInterpolateImageFunction<ImageType, 3>::Pointer interp = itk::WindowedSincInterpolateImageFunction<ImageType, 3>::New();
         resampler->SetInterpolator(interp);
         outAdd = "WindowedSinc";
         break;
     }
     default:
     {
         typename itk::NearestNeighborInterpolateImageFunction<ImageType>::Pointer interp = itk::NearestNeighborInterpolateImageFunction<ImageType>::New();
         resampler->SetInterpolator(interp);
         outAdd = "NearestNeighbour";
     }
     }
 
     resampler->Update();
 
     mitk::Image::Pointer image = mitk::Image::New();
     image->InitializeByItk( resampler->GetOutput() );
     image->SetVolume( resampler->GetOutput()->GetBufferPointer() );
     mitk::DataNode::Pointer imageNode = mitk::DataNode::New();
     imageNode->SetData( image );
-    QString name = m_SelectedImageNode->GetName().c_str();
+    QString name = node->GetName().c_str();
 
     imageNode->SetName((name+"_resampled_"+outAdd).toStdString().c_str());
-    GetDefaultDataStorage()->Add(imageNode, m_SelectedImageNode);
+    GetDefaultDataStorage()->Add(imageNode, node);
 }
 
 void QmitkPreprocessingView::DoApplyDirectionMatrix()
 {
-    bool isDiffusionImage( mitk::DiffusionPropertyHelper::IsDiffusionWeightedImage( dynamic_cast<mitk::Image *>(m_SelectedImageNode->GetData())) );
+    mitk::DataNode::Pointer node = m_Controls->m_SelctedImageComboBox->GetSelectedNode();
+    if (node.IsNull())
+        return;
+    mitk::Image::Pointer image = dynamic_cast<mitk::Image*>(node->GetData());
+
+    bool isDiffusionImage( mitk::DiffusionPropertyHelper::IsDiffusionWeightedImage(image) );
     if ( isDiffusionImage )
     {
         ItkDwiType::DirectionType newDirection;
         for (int r=0; r<3; r++)
         {
             for (int c=0; c<3; c++)
             {
                 QTableWidgetItem* item = m_Controls->m_DirectionMatrixTable->item(r,c);
                 if (!item)
                     return;
                 newDirection[r][c] = item->text().toDouble();
             }
         }
         ItkDwiType::Pointer itkDwi = ItkDwiType::New();
-        mitk::CastToItkImage(m_SelectedImage, itkDwi);
+        mitk::CastToItkImage(image, itkDwi);
 
         itk::ImageDuplicator<ItkDwiType>::Pointer duplicator = itk::ImageDuplicator<ItkDwiType>::New();
         duplicator->SetInputImage(itkDwi);
         duplicator->Update();
         itkDwi = duplicator->GetOutput();
 
         vnl_matrix_fixed< double,3,3 > oldInverseDirection = itkDwi->GetDirection().GetInverse();
-        mitk::GradientDirectionsProperty::GradientDirectionsContainerType::Pointer oldGradients = static_cast<mitk::GradientDirectionsProperty*>( m_SelectedImage->GetProperty(mitk::DiffusionPropertyHelper::GRADIENTCONTAINERPROPERTYNAME.c_str()).GetPointer() )->GetGradientDirectionsContainer();
+        mitk::GradientDirectionsProperty::GradientDirectionsContainerType::Pointer oldGradients = static_cast<mitk::GradientDirectionsProperty*>( image->GetProperty(mitk::DiffusionPropertyHelper::GRADIENTCONTAINERPROPERTYNAME.c_str()).GetPointer() )->GetGradientDirectionsContainer();
         mitk::GradientDirectionsProperty::GradientDirectionsContainerType::Pointer newGradients = mitk::GradientDirectionsProperty::GradientDirectionsContainerType::New();
 
         for (unsigned int i=0; i<oldGradients->Size(); i++)
         {
             mitk::GradientDirectionsProperty::GradientDirectionType g = oldGradients->GetElement(i);
             double mag = g.magnitude();
             g.normalize();
             mitk::GradientDirectionsProperty::GradientDirectionType newG = oldInverseDirection*g;
             newG = newDirection.GetVnlMatrix()*newG;
             newG.normalize();
             newGradients->InsertElement(i, newG*mag);
         }
 
         itkDwi->SetDirection(newDirection);
         mitk::Image::Pointer newDwi2 = mitk::GrabItkImageMemory( itkDwi.GetPointer() );
         newDwi2->SetProperty( mitk::DiffusionPropertyHelper::ORIGINALGRADIENTCONTAINERPROPERTYNAME.c_str(), mitk::GradientDirectionsProperty::New( newGradients ) );
-        newDwi2->SetProperty( mitk::DiffusionPropertyHelper::REFERENCEBVALUEPROPERTYNAME.c_str(), mitk::FloatProperty::New( static_cast<mitk::FloatProperty*>(m_SelectedImage->GetProperty(mitk::DiffusionPropertyHelper::REFERENCEBVALUEPROPERTYNAME.c_str()).GetPointer() )->GetValue() ) );
-        newDwi2->SetProperty( mitk::DiffusionPropertyHelper::MEASUREMENTFRAMEPROPERTYNAME.c_str(), mitk::MeasurementFrameProperty::New( static_cast<mitk::MeasurementFrameProperty*>(m_SelectedImage->GetProperty(mitk::DiffusionPropertyHelper::MEASUREMENTFRAMEPROPERTYNAME.c_str()).GetPointer() )->GetMeasurementFrame() ) );
+        newDwi2->SetProperty( mitk::DiffusionPropertyHelper::REFERENCEBVALUEPROPERTYNAME.c_str(), mitk::FloatProperty::New( static_cast<mitk::FloatProperty*>(image->GetProperty(mitk::DiffusionPropertyHelper::REFERENCEBVALUEPROPERTYNAME.c_str()).GetPointer() )->GetValue() ) );
+        newDwi2->SetProperty( mitk::DiffusionPropertyHelper::MEASUREMENTFRAMEPROPERTYNAME.c_str(), mitk::MeasurementFrameProperty::New( static_cast<mitk::MeasurementFrameProperty*>(image->GetProperty(mitk::DiffusionPropertyHelper::MEASUREMENTFRAMEPROPERTYNAME.c_str()).GetPointer() )->GetMeasurementFrame() ) );
 
         mitk::DiffusionPropertyHelper propertyHelper( newDwi2 );
         propertyHelper.InitializeImage();
 
         mitk::DataNode::Pointer imageNode = mitk::DataNode::New();
         imageNode->SetData( newDwi2 );
-        QString name = m_SelectedDiffusionNodes.back()->GetName().c_str();
+        QString name = node->GetName().c_str();
         imageNode->SetName((name+"_newdirection").toStdString().c_str());
-        GetDefaultDataStorage()->Add(imageNode, m_SelectedDiffusionNodes.back());
+        GetDefaultDataStorage()->Add(imageNode, node);
 
         mitk::RenderingManager::GetInstance()->InitializeViews( imageNode->GetData()->GetTimeGeometry(), mitk::RenderingManager::REQUEST_UPDATE_ALL, true );
         mitk::RenderingManager::GetInstance()->RequestUpdateAll();
     }
-    else if (m_SelectedImage.IsNotNull())
+    else
     {
-        AccessFixedDimensionByItk(m_SelectedImage, TemplatedApplyRotation,3);
+        AccessFixedDimensionByItk(image, TemplatedApplyRotation,3);
     }
 }
 
 template < typename TPixel, unsigned int VImageDimension >
 void QmitkPreprocessingView::TemplatedApplyRotation( itk::Image<TPixel, VImageDimension>* itkImage)
 {
+    mitk::DataNode::Pointer node = m_Controls->m_SelctedImageComboBox->GetSelectedNode();
+    if (node.IsNull())
+        return;
+
     ItkDwiType::DirectionType newDirection;
     for (int r=0; r<3; r++)
         for (int c=0; c<3; c++)
         {
             QTableWidgetItem* item = m_Controls->m_DirectionMatrixTable->item(r,c);
             if (!item)
                 return;
             newDirection[r][c] = item->text().toDouble();
         }
     typedef itk::Image<TPixel, VImageDimension> ImageType;
 
     typename ImageType::Pointer newImage = ImageType::New();
     newImage->SetSpacing( itkImage->GetSpacing() );
     newImage->SetOrigin( itkImage->GetOrigin() );
     newImage->SetDirection( newDirection );
     newImage->SetLargestPossibleRegion( itkImage->GetLargestPossibleRegion() );
     newImage->SetBufferedRegion( itkImage->GetLargestPossibleRegion() );
     newImage->SetRequestedRegion( itkImage->GetLargestPossibleRegion() );
     newImage->Allocate();
     newImage->FillBuffer(0);
 
     itk::ImageRegionIterator< itk::Image<TPixel, VImageDimension> > it(itkImage, itkImage->GetLargestPossibleRegion());
     while(!it.IsAtEnd())
     {
         newImage->SetPixel(it.GetIndex(), it.Get());
         ++it;
     }
 
     mitk::Image::Pointer newMitkImage = mitk::Image::New();
     newMitkImage->InitializeByItk(newImage.GetPointer());
     newMitkImage->SetVolume(newImage->GetBufferPointer());
 
     mitk::DataNode::Pointer imageNode = mitk::DataNode::New();
     imageNode->SetData( newMitkImage );
-    QString name = m_SelectedImageNode->GetName().c_str();
+    QString name = node->GetName().c_str();
     imageNode->SetName((name+"_newdirection").toStdString().c_str());
-    GetDefaultDataStorage()->Add(imageNode, m_SelectedImageNode);
+    GetDefaultDataStorage()->Add(imageNode, node);
 
     mitk::RenderingManager::GetInstance()->InitializeViews( imageNode->GetData()->GetTimeGeometry(), mitk::RenderingManager::REQUEST_UPDATE_ALL, true );
     mitk::RenderingManager::GetInstance()->RequestUpdateAll();
 }
 
 void QmitkPreprocessingView::DoProjectSignal()
 {
     switch(m_Controls->m_ProjectionMethodBox->currentIndex())
     {
     case 0:
         DoADCAverage();
         break;
     case 1:
         DoAKCFit();
         break;
     case 2:
         DoBiExpFit();
         break;
     default:
         DoADCAverage();
     }
 }
 
 void QmitkPreprocessingView::DoDwiNormalization()
 {
-    bool isDiffusionImage( mitk::DiffusionPropertyHelper::IsDiffusionWeightedImage( dynamic_cast<mitk::Image *>(m_SelectedImageNode->GetData())) );
+    mitk::DataNode::Pointer node = m_Controls->m_SelctedImageComboBox->GetSelectedNode();
+    if (node.IsNull())
+        return;
+    mitk::Image::Pointer image = dynamic_cast<mitk::Image*>(node->GetData());
+
+    bool isDiffusionImage( mitk::DiffusionPropertyHelper::IsDiffusionWeightedImage(image) );
     if ( ! isDiffusionImage )
         return;
 
-    GradientDirectionContainerType::Pointer gradientContainer = static_cast<mitk::GradientDirectionsProperty*>( m_SelectedImage->GetProperty(mitk::DiffusionPropertyHelper::GRADIENTCONTAINERPROPERTYNAME.c_str()).GetPointer() )->GetGradientDirectionsContainer();
+    GradientDirectionContainerType::Pointer gradientContainer = static_cast<mitk::GradientDirectionsProperty*>( image->GetProperty(mitk::DiffusionPropertyHelper::GRADIENTCONTAINERPROPERTYNAME.c_str()).GetPointer() )->GetGradientDirectionsContainer();
 
     int b0Index = -1;
     for (unsigned int i=0; i<gradientContainer->size(); i++)
     {
         GradientDirectionType g = gradientContainer->GetElement(i);
         if (g.magnitude()<0.001)
         {
             b0Index = i;
             break;
         }
     }
     if (b0Index==-1)
         return;
 
     typedef itk::DwiNormilzationFilter<short>  FilterType;
 
     ItkDwiType::Pointer itkVectorImagePointer = ItkDwiType::New();
-    mitk::CastToItkImage(m_SelectedImage, itkVectorImagePointer);
+    mitk::CastToItkImage(image, itkVectorImagePointer);
 
     FilterType::Pointer filter = FilterType::New();
     filter->SetInput( itkVectorImagePointer );
-    filter->SetGradientDirections( static_cast<mitk::GradientDirectionsProperty*>( m_SelectedImage->GetProperty(mitk::DiffusionPropertyHelper::GRADIENTCONTAINERPROPERTYNAME.c_str()).GetPointer() )->GetGradientDirectionsContainer() );
+    filter->SetGradientDirections( static_cast<mitk::GradientDirectionsProperty*>( image->GetProperty(mitk::DiffusionPropertyHelper::GRADIENTCONTAINERPROPERTYNAME.c_str()).GetPointer() )->GetGradientDirectionsContainer() );
 
     UcharImageType::Pointer itkImage = NULL;
     if (m_Controls->m_NormalizationMaskBox->GetSelectedNode().IsNotNull())
     {
         itkImage = UcharImageType::New();
         mitk::CastToItkImage(dynamic_cast<mitk::Image*>(m_Controls->m_NormalizationMaskBox->GetSelectedNode()->GetData()), itkImage);
         filter->SetMaskImage(itkImage);
     }
 
     // determin normalization reference
     switch(m_Controls->m_NormalizationReferenceBox->currentIndex())
     {
     case 0: // normalize relative to mean white matter signal intensity
     {
         typedef itk::DiffusionTensor3DReconstructionImageFilter< short, short, double > TensorReconstructionImageFilterType;
         TensorReconstructionImageFilterType::Pointer dtFilter = TensorReconstructionImageFilterType::New();
         dtFilter->SetGradientImage( gradientContainer, itkVectorImagePointer );
-        dtFilter->SetBValue( static_cast<mitk::FloatProperty*>(m_SelectedImage->GetProperty(mitk::DiffusionPropertyHelper::REFERENCEBVALUEPROPERTYNAME.c_str()).GetPointer() )->GetValue() );
+        dtFilter->SetBValue( static_cast<mitk::FloatProperty*>(image->GetProperty(mitk::DiffusionPropertyHelper::REFERENCEBVALUEPROPERTYNAME.c_str()).GetPointer() )->GetValue() );
         dtFilter->Update();
         itk::Image< itk::DiffusionTensor3D< double >, 3 >::Pointer tensorImage = dtFilter->GetOutput();
         itk::ImageRegionIterator< itk::Image< itk::DiffusionTensor3D< double >, 3 > > inIt(tensorImage, tensorImage->GetLargestPossibleRegion());
         double ref = 0;
         unsigned int count = 0;
         while ( !inIt.IsAtEnd() )
         {
             if (itkImage.IsNotNull() && itkImage->GetPixel(inIt.GetIndex())<=0)
             {
                 ++inIt;
                 continue;
             }
 
             double FA = inIt.Get().GetFractionalAnisotropy();
             if (FA>0.4 && FA<0.99)
             {
                 ref += itkVectorImagePointer->GetPixel(inIt.GetIndex())[b0Index];
                 count++;
             }
             ++inIt;
         }
         if (count>0)
         {
             ref /= count;
             filter->SetUseGlobalReference(true);
             filter->SetReference(ref);
         }
         break;
     }
     case 1: // normalize relative to mean CSF signal intensity
     {
         itk::AdcImageFilter< short, double >::Pointer adcFilter = itk::AdcImageFilter< short, double >::New();
         adcFilter->SetInput( itkVectorImagePointer );
         adcFilter->SetGradientDirections( gradientContainer);
-        adcFilter->SetB_value( static_cast<mitk::FloatProperty*>(m_SelectedImage->GetProperty(mitk::DiffusionPropertyHelper::REFERENCEBVALUEPROPERTYNAME.c_str()).GetPointer() )->GetValue() );
+        adcFilter->SetB_value( static_cast<mitk::FloatProperty*>(image->GetProperty(mitk::DiffusionPropertyHelper::REFERENCEBVALUEPROPERTYNAME.c_str()).GetPointer() )->GetValue() );
         adcFilter->Update();
         ItkDoubleImageType::Pointer adcImage = adcFilter->GetOutput();
         itk::ImageRegionIterator<ItkDoubleImageType> inIt(adcImage, adcImage->GetLargestPossibleRegion());
         double max = 0.0030;
         double ref = 0;
         unsigned int count = 0;
         while ( !inIt.IsAtEnd() )
         {
             if (itkImage.IsNotNull() && itkImage->GetPixel(inIt.GetIndex())<=0)
             {
                 ++inIt;
                 continue;
             }
             if (inIt.Get()>max && inIt.Get()<0.004)
             {
                 ref += itkVectorImagePointer->GetPixel(inIt.GetIndex())[b0Index];
                 count++;
             }
             ++inIt;
         }
         if (count>0)
         {
             ref /= count;
             filter->SetUseGlobalReference(true);
             filter->SetReference(ref);
         }
         break;
     }
     case 2:
     {
         filter->SetUseGlobalReference(false);
     }
     }
     filter->Update();
 
-    mitk::Image::Pointer image = mitk::GrabItkImageMemory( filter->GetOutput() );
-    image->SetProperty( mitk::DiffusionPropertyHelper::GRADIENTCONTAINERPROPERTYNAME.c_str(), mitk::GradientDirectionsProperty::New( static_cast<mitk::GradientDirectionsProperty*>( m_SelectedImage->GetProperty(mitk::DiffusionPropertyHelper::GRADIENTCONTAINERPROPERTYNAME.c_str()).GetPointer() )->GetGradientDirectionsContainer() ) );
-    image->SetProperty( mitk::DiffusionPropertyHelper::REFERENCEBVALUEPROPERTYNAME.c_str(), mitk::FloatProperty::New( static_cast<mitk::FloatProperty*>(m_SelectedImage->GetProperty(mitk::DiffusionPropertyHelper::REFERENCEBVALUEPROPERTYNAME.c_str()).GetPointer() )->GetValue() ) );
-    image->SetProperty( mitk::DiffusionPropertyHelper::MEASUREMENTFRAMEPROPERTYNAME.c_str(), mitk::MeasurementFrameProperty::New( static_cast<mitk::MeasurementFrameProperty*>(m_SelectedImage->GetProperty(mitk::DiffusionPropertyHelper::MEASUREMENTFRAMEPROPERTYNAME.c_str()).GetPointer() )->GetMeasurementFrame() ) );
-    mitk::DiffusionPropertyHelper propertyHelper( image );
+    mitk::Image::Pointer newImage = mitk::GrabItkImageMemory( filter->GetOutput() );
+    newImage->SetProperty( mitk::DiffusionPropertyHelper::GRADIENTCONTAINERPROPERTYNAME.c_str(), mitk::GradientDirectionsProperty::New( static_cast<mitk::GradientDirectionsProperty*>( image->GetProperty(mitk::DiffusionPropertyHelper::GRADIENTCONTAINERPROPERTYNAME.c_str()).GetPointer() )->GetGradientDirectionsContainer() ) );
+    newImage->SetProperty( mitk::DiffusionPropertyHelper::REFERENCEBVALUEPROPERTYNAME.c_str(), mitk::FloatProperty::New( static_cast<mitk::FloatProperty*>(image->GetProperty(mitk::DiffusionPropertyHelper::REFERENCEBVALUEPROPERTYNAME.c_str()).GetPointer() )->GetValue() ) );
+    newImage->SetProperty( mitk::DiffusionPropertyHelper::MEASUREMENTFRAMEPROPERTYNAME.c_str(), mitk::MeasurementFrameProperty::New( static_cast<mitk::MeasurementFrameProperty*>(image->GetProperty(mitk::DiffusionPropertyHelper::MEASUREMENTFRAMEPROPERTYNAME.c_str()).GetPointer() )->GetMeasurementFrame() ) );
+    mitk::DiffusionPropertyHelper propertyHelper( newImage );
     propertyHelper.InitializeImage();
 
     mitk::DataNode::Pointer imageNode = mitk::DataNode::New();
-    imageNode->SetData( image );
-    QString name = m_SelectedDiffusionNodes.back()->GetName().c_str();
+    imageNode->SetData( newImage );
+    QString name = node->GetName().c_str();
 
     imageNode->SetName((name+"_normalized").toStdString().c_str());
-    GetDefaultDataStorage()->Add(imageNode, m_SelectedDiffusionNodes.back());
+    GetDefaultDataStorage()->Add(imageNode, node);
 }
 
 void QmitkPreprocessingView::DoLengthCorrection()
 {
-    bool isDiffusionImage( mitk::DiffusionPropertyHelper::IsDiffusionWeightedImage( dynamic_cast<mitk::Image *>(m_SelectedImageNode->GetData())) );
+    mitk::DataNode::Pointer node = m_Controls->m_SelctedImageComboBox->GetSelectedNode();
+    if (node.IsNull())
+        return;
+    mitk::Image::Pointer image = dynamic_cast<mitk::Image*>(node->GetData());
+
+    bool isDiffusionImage( mitk::DiffusionPropertyHelper::IsDiffusionWeightedImage(image) );
     if ( ! isDiffusionImage )
         return;
 
     typedef itk::DwiGradientLengthCorrectionFilter  FilterType;
 
     ItkDwiType::Pointer itkVectorImagePointer = ItkDwiType::New();
-    mitk::CastToItkImage(m_SelectedImage, itkVectorImagePointer);
+    mitk::CastToItkImage(image, itkVectorImagePointer);
 
     FilterType::Pointer filter = FilterType::New();
     filter->SetRoundingValue( m_Controls->m_B_ValueMap_Rounder_SpinBox->value());
-    filter->SetReferenceBValue( static_cast<mitk::FloatProperty*>(m_SelectedImage->GetProperty(mitk::DiffusionPropertyHelper::REFERENCEBVALUEPROPERTYNAME.c_str()).GetPointer() )->GetValue() );
-    filter->SetReferenceGradientDirectionContainer( static_cast<mitk::GradientDirectionsProperty*>( m_SelectedImage->GetProperty(mitk::DiffusionPropertyHelper::GRADIENTCONTAINERPROPERTYNAME.c_str()).GetPointer() )->GetGradientDirectionsContainer() );
+    filter->SetReferenceBValue( static_cast<mitk::FloatProperty*>(image->GetProperty(mitk::DiffusionPropertyHelper::REFERENCEBVALUEPROPERTYNAME.c_str()).GetPointer() )->GetValue() );
+    filter->SetReferenceGradientDirectionContainer( static_cast<mitk::GradientDirectionsProperty*>( image->GetProperty(mitk::DiffusionPropertyHelper::GRADIENTCONTAINERPROPERTYNAME.c_str()).GetPointer() )->GetGradientDirectionsContainer() );
     filter->Update();
 
-    mitk::Image::Pointer image = mitk::ImportItkImage( itkVectorImagePointer );
-    image->SetProperty( mitk::DiffusionPropertyHelper::GRADIENTCONTAINERPROPERTYNAME.c_str(), mitk::GradientDirectionsProperty::New( filter->GetOutputGradientDirectionContainer() ) );
-    image->SetProperty( mitk::DiffusionPropertyHelper::REFERENCEBVALUEPROPERTYNAME.c_str(), mitk::FloatProperty::New( filter->GetNewBValue() ) );
-    image->SetProperty( mitk::DiffusionPropertyHelper::MEASUREMENTFRAMEPROPERTYNAME.c_str(), mitk::MeasurementFrameProperty::New( static_cast<mitk::MeasurementFrameProperty*>(m_SelectedImage->GetProperty(mitk::DiffusionPropertyHelper::MEASUREMENTFRAMEPROPERTYNAME.c_str()).GetPointer() )->GetMeasurementFrame() ) );
-    mitk::DiffusionPropertyHelper propertyHelper( image );
+    mitk::Image::Pointer newImage = mitk::ImportItkImage( itkVectorImagePointer );
+    newImage->SetProperty( mitk::DiffusionPropertyHelper::GRADIENTCONTAINERPROPERTYNAME.c_str(), mitk::GradientDirectionsProperty::New( filter->GetOutputGradientDirectionContainer() ) );
+    newImage->SetProperty( mitk::DiffusionPropertyHelper::REFERENCEBVALUEPROPERTYNAME.c_str(), mitk::FloatProperty::New( filter->GetNewBValue() ) );
+    newImage->SetProperty( mitk::DiffusionPropertyHelper::MEASUREMENTFRAMEPROPERTYNAME.c_str(), mitk::MeasurementFrameProperty::New( static_cast<mitk::MeasurementFrameProperty*>(image->GetProperty(mitk::DiffusionPropertyHelper::MEASUREMENTFRAMEPROPERTYNAME.c_str()).GetPointer() )->GetMeasurementFrame() ) );
+    mitk::DiffusionPropertyHelper propertyHelper( newImage );
     propertyHelper.InitializeImage();
 
     mitk::DataNode::Pointer imageNode = mitk::DataNode::New();
-    imageNode->SetData( image );
-    QString name = m_SelectedDiffusionNodes.back()->GetName().c_str();
+    imageNode->SetData( newImage );
+    QString name = node->GetName().c_str();
 
     imageNode->SetName((name+"_rounded").toStdString().c_str());
-    GetDefaultDataStorage()->Add(imageNode, m_SelectedDiffusionNodes.back());
+    GetDefaultDataStorage()->Add(imageNode, node);
 }
 
 void QmitkPreprocessingView::UpdateDwiBValueMapRounder(int i)
 {
-    bool isDiffusionImage( mitk::DiffusionPropertyHelper::IsDiffusionWeightedImage( dynamic_cast<mitk::Image *>(m_SelectedImageNode->GetData())) );
+    mitk::DataNode::Pointer node = m_Controls->m_SelctedImageComboBox->GetSelectedNode();
+    if (node.IsNull())
+        return;
+
+    bool isDiffusionImage( mitk::DiffusionPropertyHelper::IsDiffusionWeightedImage(node) );
     if ( ! isDiffusionImage )
         return;
-    //m_DiffusionImage->UpdateBValueMap();
+
     UpdateBValueTableWidget(i);
 }
 
-void QmitkPreprocessingView::CallMultishellToSingleShellFilter(itk::DWIVoxelFunctor * functor, mitk::Image::Pointer ImPtr, QString imageName, mitk::DataNode* parent)
+void QmitkPreprocessingView::CallMultishellToSingleShellFilter(itk::DWIVoxelFunctor * functor, mitk::Image::Pointer image, QString imageName, mitk::DataNode* parent)
 {
     typedef itk::RadialMultishellToSingleshellImageFilter<DiffusionPixelType, DiffusionPixelType> FilterType;
 
     // filter input parameter
     const mitk::BValueMapProperty::BValueMap
-            &originalShellMap  = static_cast<mitk::BValueMapProperty*>(m_SelectedImage->GetProperty(mitk::DiffusionPropertyHelper::BVALUEMAPPROPERTYNAME.c_str()).GetPointer() )->GetBValueMap();
+            &originalShellMap  = static_cast<mitk::BValueMapProperty*>(image->GetProperty(mitk::DiffusionPropertyHelper::BVALUEMAPPROPERTYNAME.c_str()).GetPointer() )->GetBValueMap();
 
     ItkDwiType::Pointer itkVectorImagePointer = ItkDwiType::New();
-    mitk::CastToItkImage(m_SelectedImage, itkVectorImagePointer);
+    mitk::CastToItkImage(image, itkVectorImagePointer);
     ItkDwiType
             *vectorImage       = itkVectorImagePointer.GetPointer();
 
     const mitk::GradientDirectionsProperty::GradientDirectionsContainerType::Pointer
-            gradientContainer = static_cast<mitk::GradientDirectionsProperty*>( m_SelectedImage->GetProperty(mitk::DiffusionPropertyHelper::GRADIENTCONTAINERPROPERTYNAME.c_str()).GetPointer() )->GetGradientDirectionsContainer();
+            gradientContainer = static_cast<mitk::GradientDirectionsProperty*>( image->GetProperty(mitk::DiffusionPropertyHelper::GRADIENTCONTAINERPROPERTYNAME.c_str()).GetPointer() )->GetGradientDirectionsContainer();
 
     const unsigned int
-            &bValue            = static_cast<mitk::FloatProperty*>(m_SelectedImage->GetProperty(mitk::DiffusionPropertyHelper::REFERENCEBVALUEPROPERTYNAME.c_str()).GetPointer() )->GetValue();
+            &bValue            = static_cast<mitk::FloatProperty*>(image->GetProperty(mitk::DiffusionPropertyHelper::REFERENCEBVALUEPROPERTYNAME.c_str()).GetPointer() )->GetValue();
 
     mitk::DataNode::Pointer imageNode = 0;
 
     // filter call
     FilterType::Pointer filter = FilterType::New();
     filter->SetInput(vectorImage);
     filter->SetOriginalGradientDirections(gradientContainer);
     filter->SetOriginalBValueMap(originalShellMap);
     filter->SetOriginalBValue(bValue);
     filter->SetFunctor(functor);
     filter->Update();
 
     // create new DWI image
     mitk::Image::Pointer outImage = mitk::GrabItkImageMemory( filter->GetOutput() );
     outImage->SetProperty( mitk::DiffusionPropertyHelper::GRADIENTCONTAINERPROPERTYNAME.c_str(), mitk::GradientDirectionsProperty::New( filter->GetTargetGradientDirections() ) );
     outImage->SetProperty( mitk::DiffusionPropertyHelper::REFERENCEBVALUEPROPERTYNAME.c_str(), mitk::FloatProperty::New( m_Controls->m_targetBValueSpinBox->value() ) );
-    outImage->SetProperty( mitk::DiffusionPropertyHelper::MEASUREMENTFRAMEPROPERTYNAME.c_str(), mitk::MeasurementFrameProperty::New( static_cast<mitk::MeasurementFrameProperty*>(m_SelectedImage->GetProperty(mitk::DiffusionPropertyHelper::MEASUREMENTFRAMEPROPERTYNAME.c_str()).GetPointer() )->GetMeasurementFrame() ) );
+    outImage->SetProperty( mitk::DiffusionPropertyHelper::MEASUREMENTFRAMEPROPERTYNAME.c_str(), mitk::MeasurementFrameProperty::New( static_cast<mitk::MeasurementFrameProperty*>(image->GetProperty(mitk::DiffusionPropertyHelper::MEASUREMENTFRAMEPROPERTYNAME.c_str()).GetPointer() )->GetMeasurementFrame() ) );
     mitk::DiffusionPropertyHelper propertyHelper( outImage );
     propertyHelper.InitializeImage();
 
     imageNode = mitk::DataNode::New();
     imageNode->SetData( outImage );
     imageNode->SetName(imageName.toStdString().c_str());
     GetDefaultDataStorage()->Add(imageNode, parent);
 
     //  if(m_Controls->m_OutputRMSErrorImage->isChecked()){
     //    // create new Error image
     //    FilterType::ErrorImageType::Pointer errImage = filter->GetErrorImage();
     //    mitk::Image::Pointer mitkErrImage = mitk::Image::New();
     //    mitkErrImage->InitializeByItk<FilterType::ErrorImageType>(errImage);
     //    mitkErrImage->SetVolume(errImage->GetBufferPointer());
 
     //    imageNode = mitk::DataNode::New();
     //    imageNode->SetData( mitkErrImage );
     //    imageNode->SetName((imageName+"_Error").toStdString().c_str());
     //    GetDefaultDataStorage()->Add(imageNode);
     //  }
 }
 
 void QmitkPreprocessingView::DoBiExpFit()
 {
-    itk::BiExpFitFunctor::Pointer functor = itk::BiExpFitFunctor::New();
-
-    for (unsigned int i=0; i<m_SelectedDiffusionNodes.size(); i++)
-    {
-        mitk::Image::Pointer inImage =
-                dynamic_cast< mitk::Image* >(m_SelectedDiffusionNodes.at(i)->GetData());
+    mitk::DataNode::Pointer node = m_Controls->m_SelctedImageComboBox->GetSelectedNode();
+    if (node.IsNull())
+        return;
+    mitk::Image::Pointer image = dynamic_cast<mitk::Image*>(node->GetData());
 
-        QString name(m_SelectedDiffusionNodes.at(i)->GetName().c_str());
+    bool isDiffusionImage( mitk::DiffusionPropertyHelper::IsDiffusionWeightedImage(image) );
+    if ( ! isDiffusionImage )
+        return;
 
-        const mitk::BValueMapProperty::BValueMap
-                &originalShellMap  = static_cast<mitk::BValueMapProperty*>(inImage->GetProperty(mitk::DiffusionPropertyHelper::BVALUEMAPPROPERTYNAME.c_str()).GetPointer() )->GetBValueMap();
+    itk::BiExpFitFunctor::Pointer functor = itk::BiExpFitFunctor::New();
 
-        mitk::BValueMapProperty::BValueMap::const_iterator it = originalShellMap.begin();
-        ++it;/* skip b=0*/ unsigned int s = 0; /*shell index */
-        vnl_vector<double> bValueList(originalShellMap.size()-1);
-        while(it != originalShellMap.end())
-            bValueList.put(s++,(it++)->first);
+    QString name(node->GetName().c_str());
 
-        const double targetBValue = m_Controls->m_targetBValueSpinBox->value();
-        functor->setListOfBValues(bValueList);
-        functor->setTargetBValue(targetBValue);
-        CallMultishellToSingleShellFilter(functor,inImage,name + "_BiExp", m_SelectedDiffusionNodes.at(i));
-    }
+    const mitk::BValueMapProperty::BValueMap
+            &originalShellMap  = static_cast<mitk::BValueMapProperty*>(image->GetProperty(mitk::DiffusionPropertyHelper::BVALUEMAPPROPERTYNAME.c_str()).GetPointer() )->GetBValueMap();
+
+    mitk::BValueMapProperty::BValueMap::const_iterator it = originalShellMap.begin();
+    ++it;/* skip b=0*/ unsigned int s = 0; /*shell index */
+    vnl_vector<double> bValueList(originalShellMap.size()-1);
+    while(it != originalShellMap.end())
+        bValueList.put(s++,(it++)->first);
+
+    const double targetBValue = m_Controls->m_targetBValueSpinBox->value();
+    functor->setListOfBValues(bValueList);
+    functor->setTargetBValue(targetBValue);
+    CallMultishellToSingleShellFilter(functor,image,name + "_BiExp", node);
 }
 
 void QmitkPreprocessingView::DoAKCFit()
 {
-    itk::KurtosisFitFunctor::Pointer functor = itk::KurtosisFitFunctor::New();
-
-    for (unsigned int i=0; i<m_SelectedDiffusionNodes.size(); i++)
-    {
-        mitk::Image::Pointer inImage =
-                dynamic_cast< mitk::Image* >(m_SelectedDiffusionNodes.at(i)->GetData());
+    mitk::DataNode::Pointer node = m_Controls->m_SelctedImageComboBox->GetSelectedNode();
+    if (node.IsNull())
+        return;
+    mitk::Image::Pointer image = dynamic_cast<mitk::Image*>(node->GetData());
 
-        QString name(m_SelectedDiffusionNodes.at(i)->GetName().c_str());
+    bool isDiffusionImage( mitk::DiffusionPropertyHelper::IsDiffusionWeightedImage(image) );
+    if ( ! isDiffusionImage )
+        return;
 
-        const mitk::BValueMapProperty::BValueMap
-                &originalShellMap  = static_cast<mitk::BValueMapProperty*>(inImage->GetProperty(mitk::DiffusionPropertyHelper::BVALUEMAPPROPERTYNAME.c_str()).GetPointer() )->GetBValueMap();
+    itk::KurtosisFitFunctor::Pointer functor = itk::KurtosisFitFunctor::New();
 
-        mitk::BValueMapProperty::BValueMap::const_iterator it = originalShellMap.begin();
-        ++it;/* skip b=0*/ unsigned int s = 0; /*shell index */
-        vnl_vector<double> bValueList(originalShellMap.size()-1);
-        while(it != originalShellMap.end())
-            bValueList.put(s++,(it++)->first);
+    QString name(node->GetName().c_str());
 
-        const double targetBValue = m_Controls->m_targetBValueSpinBox->value();
-        functor->setListOfBValues(bValueList);
-        functor->setTargetBValue(targetBValue);
-        CallMultishellToSingleShellFilter(functor,inImage,name + "_AKC", m_SelectedDiffusionNodes.at(i));
-    }
+    const mitk::BValueMapProperty::BValueMap
+            &originalShellMap  = static_cast<mitk::BValueMapProperty*>(image->GetProperty(mitk::DiffusionPropertyHelper::BVALUEMAPPROPERTYNAME.c_str()).GetPointer() )->GetBValueMap();
+
+    mitk::BValueMapProperty::BValueMap::const_iterator it = originalShellMap.begin();
+    ++it;/* skip b=0*/ unsigned int s = 0; /*shell index */
+    vnl_vector<double> bValueList(originalShellMap.size()-1);
+    while(it != originalShellMap.end())
+        bValueList.put(s++,(it++)->first);
+
+    const double targetBValue = m_Controls->m_targetBValueSpinBox->value();
+    functor->setListOfBValues(bValueList);
+    functor->setTargetBValue(targetBValue);
+    CallMultishellToSingleShellFilter(functor,image,name + "_AKC", node);
 }
 
 void QmitkPreprocessingView::DoADCFit()
 {
     // later
 }
 
 void QmitkPreprocessingView::DoADCAverage()
 {
-    itk::ADCAverageFunctor::Pointer functor = itk::ADCAverageFunctor::New();
-
-    for (unsigned int i=0; i<m_SelectedDiffusionNodes.size(); i++)
-    {
-        mitk::Image::Pointer inImage =
-                dynamic_cast< mitk::Image* >(m_SelectedDiffusionNodes.at(i)->GetData());
+    mitk::DataNode::Pointer node = m_Controls->m_SelctedImageComboBox->GetSelectedNode();
+    if (node.IsNull())
+        return;
+    mitk::Image::Pointer image = dynamic_cast<mitk::Image*>(node->GetData());
 
-        QString name(m_SelectedDiffusionNodes.at(i)->GetName().c_str());
+    bool isDiffusionImage( mitk::DiffusionPropertyHelper::IsDiffusionWeightedImage(image) );
+    if ( ! isDiffusionImage )
+        return;
 
-        const mitk::BValueMapProperty::BValueMap
-                &originalShellMap  = static_cast<mitk::BValueMapProperty*>(inImage->GetProperty(mitk::DiffusionPropertyHelper::BVALUEMAPPROPERTYNAME.c_str()).GetPointer() )->GetBValueMap();
+    itk::ADCAverageFunctor::Pointer functor = itk::ADCAverageFunctor::New();
 
-        mitk::BValueMapProperty::BValueMap::const_iterator it = originalShellMap.begin();
-        ++it;/* skip b=0*/ unsigned int s = 0; /*shell index */
-        vnl_vector<double> bValueList(originalShellMap.size()-1);
-        while(it != originalShellMap.end())
-            bValueList.put(s++,(it++)->first);
+    QString name(node->GetName().c_str());
 
-        const double targetBValue = m_Controls->m_targetBValueSpinBox->value();
-        functor->setListOfBValues(bValueList);
-        functor->setTargetBValue(targetBValue);
-        CallMultishellToSingleShellFilter(functor,inImage,name + "_ADC", m_SelectedDiffusionNodes.at(i));
-    }
+    const mitk::BValueMapProperty::BValueMap
+            &originalShellMap  = static_cast<mitk::BValueMapProperty*>(image->GetProperty(mitk::DiffusionPropertyHelper::BVALUEMAPPROPERTYNAME.c_str()).GetPointer() )->GetBValueMap();
+
+    mitk::BValueMapProperty::BValueMap::const_iterator it = originalShellMap.begin();
+    ++it;/* skip b=0*/ unsigned int s = 0; /*shell index */
+    vnl_vector<double> bValueList(originalShellMap.size()-1);
+    while(it != originalShellMap.end())
+        bValueList.put(s++,(it++)->first);
+
+    const double targetBValue = m_Controls->m_targetBValueSpinBox->value();
+    functor->setListOfBValues(bValueList);
+    functor->setTargetBValue(targetBValue);
+    CallMultishellToSingleShellFilter(functor,image,name + "_ADC", node);
 }
 
 void QmitkPreprocessingView::DoAdcCalculation()
 {
-    bool isDiffusionImage( mitk::DiffusionPropertyHelper::IsDiffusionWeightedImage( dynamic_cast<mitk::Image *>(m_SelectedImageNode->GetData())) );
+    mitk::DataNode::Pointer node = m_Controls->m_SelctedImageComboBox->GetSelectedNode();
+    if (node.IsNull())
+        return;
+    mitk::Image::Pointer image = dynamic_cast<mitk::Image*>(node->GetData());
+
+    bool isDiffusionImage( mitk::DiffusionPropertyHelper::IsDiffusionWeightedImage(image) );
     if ( ! isDiffusionImage )
         return;
 
     typedef itk::AdcImageFilter< DiffusionPixelType, double >     FilterType;
 
+    ItkDwiType::Pointer itkVectorImagePointer = ItkDwiType::New();
+    mitk::CastToItkImage(image, itkVectorImagePointer);
+    FilterType::Pointer filter = FilterType::New();
+    filter->SetInput( itkVectorImagePointer );
+    filter->SetGradientDirections( static_cast<mitk::GradientDirectionsProperty*>( image->GetProperty(mitk::DiffusionPropertyHelper::GRADIENTCONTAINERPROPERTYNAME.c_str()).GetPointer() )->GetGradientDirectionsContainer() );
+    filter->SetB_value( static_cast<mitk::FloatProperty*>(image->GetProperty(mitk::DiffusionPropertyHelper::REFERENCEBVALUEPROPERTYNAME.c_str()).GetPointer() )->GetValue() );
+    filter->Update();
 
-    for (unsigned int i=0; i<m_SelectedDiffusionNodes.size(); i++)
-    {
-        mitk::Image::Pointer inImage = dynamic_cast< mitk::Image* >(m_SelectedDiffusionNodes.at(i)->GetData());
-        ItkDwiType::Pointer itkVectorImagePointer = ItkDwiType::New();
-        mitk::CastToItkImage(inImage, itkVectorImagePointer);
-        FilterType::Pointer filter = FilterType::New();
-        filter->SetInput( itkVectorImagePointer );
-        filter->SetGradientDirections( static_cast<mitk::GradientDirectionsProperty*>( inImage->GetProperty(mitk::DiffusionPropertyHelper::GRADIENTCONTAINERPROPERTYNAME.c_str()).GetPointer() )->GetGradientDirectionsContainer() );
-        filter->SetB_value( static_cast<mitk::FloatProperty*>(inImage->GetProperty(mitk::DiffusionPropertyHelper::REFERENCEBVALUEPROPERTYNAME.c_str()).GetPointer() )->GetValue() );
-        filter->Update();
-
-        mitk::Image::Pointer image = mitk::Image::New();
-        image->InitializeByItk( filter->GetOutput() );
-        image->SetVolume( filter->GetOutput()->GetBufferPointer() );
-        mitk::DataNode::Pointer imageNode = mitk::DataNode::New();
-        imageNode->SetData( image );
-        QString name = m_SelectedDiffusionNodes.at(i)->GetName().c_str();
+    mitk::Image::Pointer newImage = mitk::Image::New();
+    newImage->InitializeByItk( filter->GetOutput() );
+    newImage->SetVolume( filter->GetOutput()->GetBufferPointer() );
+    mitk::DataNode::Pointer imageNode = mitk::DataNode::New();
+    imageNode->SetData( newImage );
+    QString name = node->GetName().c_str();
 
-        imageNode->SetName((name+"_ADC").toStdString().c_str());
-        GetDefaultDataStorage()->Add(imageNode, m_SelectedDiffusionNodes.at(i));
-    }
+    imageNode->SetName((name+"_ADC").toStdString().c_str());
+    GetDefaultDataStorage()->Add(imageNode, node);
 }
 
 
 void QmitkPreprocessingView::UpdateBValueTableWidget(int i)
 {
+    mitk::DataNode::Pointer node = m_Controls->m_SelctedImageComboBox->GetSelectedNode();
+    if (node.IsNull())
+        return;
+    mitk::Image::Pointer image = dynamic_cast<mitk::Image*>(node->GetData());
+
     bool isDiffusionImage(false);
-    if( m_SelectedImageNode && m_SelectedImageNode.IsNotNull() )
-    {
-        isDiffusionImage = mitk::DiffusionPropertyHelper::IsDiffusionWeightedImage( dynamic_cast<mitk::Image *>(m_SelectedImageNode->GetData()));
-    }
+    isDiffusionImage = mitk::DiffusionPropertyHelper::IsDiffusionWeightedImage(image);
 
     if ( ! isDiffusionImage )
     {
         m_Controls->m_B_ValueMap_TableWidget->clear();
         m_Controls->m_B_ValueMap_TableWidget->setRowCount(1);
         QStringList headerList;
         headerList << "b-Value" << "Number of gradients";
         m_Controls->m_B_ValueMap_TableWidget->setHorizontalHeaderLabels(headerList);
         m_Controls->m_B_ValueMap_TableWidget->setItem(0,0,new QTableWidgetItem("-"));
         m_Controls->m_B_ValueMap_TableWidget->setItem(0,1,new QTableWidgetItem("-"));
     }else{
 
         typedef mitk::BValueMapProperty::BValueMap BValueMap;
         typedef mitk::BValueMapProperty::BValueMap::iterator BValueMapIterator;
 
         BValueMapIterator it;
 
-        BValueMap roundedBValueMap = static_cast<mitk::BValueMapProperty*>(m_SelectedImage->GetProperty(mitk::DiffusionPropertyHelper::BVALUEMAPPROPERTYNAME.c_str()).GetPointer() )->GetBValueMap();
+        BValueMap roundedBValueMap = static_cast<mitk::BValueMapProperty*>(image->GetProperty(mitk::DiffusionPropertyHelper::BVALUEMAPPROPERTYNAME.c_str()).GetPointer() )->GetBValueMap();
 
         m_Controls->m_B_ValueMap_TableWidget->clear();
         m_Controls->m_B_ValueMap_TableWidget->setRowCount(roundedBValueMap.size() );
         QStringList headerList;
         headerList << "b-Value" << "Number of gradients";
         m_Controls->m_B_ValueMap_TableWidget->setHorizontalHeaderLabels(headerList);
 
         int i = 0 ;
         for(it = roundedBValueMap.begin() ;it != roundedBValueMap.end(); it++)
         {
             m_Controls->m_B_ValueMap_TableWidget->setItem(i,0,new QTableWidgetItem(QString::number(it->first)));
             QTableWidgetItem* item = m_Controls->m_B_ValueMap_TableWidget->item(i,0);
             item->setFlags(item->flags() & ~Qt::ItemIsEditable);
             m_Controls->m_B_ValueMap_TableWidget->setItem(i,1,new QTableWidgetItem(QString::number(it->second.size())));
             i++;
         }
     }
 
 }
 
 
 template < typename TPixel, unsigned int VImageDimension >
 void QmitkPreprocessingView::TemplatedUpdateGui( itk::Image<TPixel, VImageDimension>* itkImage)
 {
     for (int r=0; r<3; r++)
         for (int c=0; c<3; c++)
         {
             QTableWidgetItem* item = m_Controls->m_DirectionMatrixTable->item(r,c);
             delete item;
             item = new QTableWidgetItem();
             item->setTextAlignment(Qt::AlignCenter | Qt::AlignVCenter);
             item->setText(QString::number(itkImage->GetDirection()[r][c]));
             m_Controls->m_DirectionMatrixTable->setItem(r,c,item);
         }
 }
 
-void QmitkPreprocessingView::OnSelectionChanged( std::vector<mitk::DataNode*> nodes )
+void QmitkPreprocessingView::OnImageSelectionChanged()
 {
-    bool foundDwiVolume = false;
-    bool foundImageVolume = false;
-    m_SelectedImage = NULL;
-    m_SelectedImageNode = NULL;
-    m_SelectedDiffusionNodes.clear();
-
-    // iterate selection
-    for( std::vector<mitk::DataNode*>::iterator it = nodes.begin(); it != nodes.end(); ++it )
-    {
-        mitk::DataNode::Pointer node = *it;
-
-        if( node.IsNotNull() && dynamic_cast<mitk::Image*>(node->GetData()) )
-        {
-            foundImageVolume = true;
-            m_SelectedImage = dynamic_cast<mitk::Image*>(node->GetData());
-            m_Controls->m_DiffusionImageLabel->setText(node->GetName().c_str());
-            m_SelectedImageNode = node;
-
-            bool isDiffusionImage( mitk::DiffusionPropertyHelper::IsDiffusionWeightedImage( m_SelectedImageNode ) );
-            if( isDiffusionImage )
-            {
-                foundDwiVolume = true;
-                m_SelectedDiffusionNodes.push_back(node);
-            }
-        }
-    }
+    bool foundImageVolume = true;
+    mitk::DataNode::Pointer node = m_Controls->m_SelctedImageComboBox->GetSelectedNode();
+    if (node.IsNull())
+        foundImageVolume;
+    bool foundDwiVolume( mitk::DiffusionPropertyHelper::IsDiffusionWeightedImage( node ) );
 
     m_Controls->m_ButtonAverageGradients->setEnabled(foundDwiVolume);
     m_Controls->m_ButtonExtractB0->setEnabled(foundDwiVolume);
     m_Controls->m_CheckExtractAll->setEnabled(foundDwiVolume);
     m_Controls->m_ModifyMeasurementFrame->setEnabled(foundDwiVolume);
     m_Controls->m_MeasurementFrameTable->setEnabled(foundDwiVolume);
     m_Controls->m_ReduceGradientsButton->setEnabled(foundDwiVolume);
     m_Controls->m_ShowGradientsButton->setEnabled(foundDwiVolume);
     m_Controls->m_MirrorGradientToHalfSphereButton->setEnabled(foundDwiVolume);
     m_Controls->m_MergeDwisButton->setEnabled(foundDwiVolume);
     m_Controls->m_B_ValueMap_Rounder_SpinBox->setEnabled(foundDwiVolume);
     m_Controls->m_ProjectSignalButton->setEnabled(foundDwiVolume);
     m_Controls->m_CreateLengthCorrectedDwi->setEnabled(foundDwiVolume);
     m_Controls->m_CalcAdcButton->setEnabled(foundDwiVolume);
     m_Controls->m_targetBValueSpinBox->setEnabled(foundDwiVolume);
     m_Controls->m_NormalizeImageValuesButton->setEnabled(foundDwiVolume);
     m_Controls->m_DirectionMatrixTable->setEnabled(foundImageVolume);
     m_Controls->m_ModifyDirection->setEnabled(foundImageVolume);
     m_Controls->m_ExtractBrainMask->setEnabled(foundImageVolume);
     m_Controls->m_ResampleImageButton->setEnabled(foundImageVolume);
     m_Controls->m_ModifySpacingButton->setEnabled(foundImageVolume);
     m_Controls->m_ModifyOriginButton->setEnabled(foundImageVolume);
     m_Controls->m_CropImageButton->setEnabled(foundImageVolume);
     m_Controls->m_RemoveGradientButton->setEnabled(foundDwiVolume);
     m_Controls->m_ExtractGradientButton->setEnabled(foundDwiVolume);
+    m_Controls->m_FlipAxis->setEnabled(foundImageVolume);
 
     // reset sampling frame to 1 and update all ealted components
     m_Controls->m_B_ValueMap_Rounder_SpinBox->setValue(1);
 
     UpdateBValueTableWidget(m_Controls->m_B_ValueMap_Rounder_SpinBox->value());
     DoUpdateInterpolationGui(m_Controls->m_ResampleTypeBox->currentIndex());
 
-    if( m_SelectedImageNode.IsNull() )
-    {
-        return;
-    }
-
-    bool isDiffusionImage( mitk::DiffusionPropertyHelper::IsDiffusionWeightedImage( m_SelectedImageNode) );
-
-    if (foundDwiVolume && isDiffusionImage)
+    mitk::Image::Pointer image = dynamic_cast<mitk::Image*>(node->GetData());
+    if (foundDwiVolume)
     {
         m_Controls->m_InputData->setTitle("Input Data");
-        vnl_matrix_fixed< double, 3, 3 > mf = static_cast<mitk::MeasurementFrameProperty*>(m_SelectedImage->GetProperty(mitk::DiffusionPropertyHelper::MEASUREMENTFRAMEPROPERTYNAME.c_str()).GetPointer() )->GetMeasurementFrame();
+        vnl_matrix_fixed< double, 3, 3 > mf = static_cast<mitk::MeasurementFrameProperty*>(image->GetProperty(mitk::DiffusionPropertyHelper::MEASUREMENTFRAMEPROPERTYNAME.c_str()).GetPointer() )->GetMeasurementFrame();
         for (int r=0; r<3; r++)
             for (int c=0; c<3; c++)
             {
                 // Measurement frame
                 {
                     QTableWidgetItem* item = m_Controls->m_MeasurementFrameTable->item(r,c);
                     delete item;
                     item = new QTableWidgetItem();
                     item->setTextAlignment(Qt::AlignCenter | Qt::AlignVCenter);
                     item->setText(QString::number(mf.get(r,c)));
                     m_Controls->m_MeasurementFrameTable->setItem(r,c,item);
                 }
 
                 // Direction matrix
                 {
                     ItkDwiType::Pointer itkVectorImagePointer = ItkDwiType::New();
-                    mitk::CastToItkImage(m_SelectedImage, itkVectorImagePointer);
+                    mitk::CastToItkImage(image, itkVectorImagePointer);
 
                     QTableWidgetItem* item = m_Controls->m_DirectionMatrixTable->item(r,c);
                     delete item;
                     item = new QTableWidgetItem();
                     item->setTextAlignment(Qt::AlignCenter | Qt::AlignVCenter);
                     item->setText(QString::number(itkVectorImagePointer->GetDirection()[r][c]));
                     m_Controls->m_DirectionMatrixTable->setItem(r,c,item);
                 }
             }
 
         //calculate target bValue for MultishellToSingleShellfilter
-        const mitk::BValueMapProperty::BValueMap & bValMap = static_cast<mitk::BValueMapProperty*>(m_SelectedImage->GetProperty(mitk::DiffusionPropertyHelper::BVALUEMAPPROPERTYNAME.c_str()).GetPointer() )->GetBValueMap();
+        const mitk::BValueMapProperty::BValueMap & bValMap = static_cast<mitk::BValueMapProperty*>(image->GetProperty(mitk::DiffusionPropertyHelper::BVALUEMAPPROPERTYNAME.c_str()).GetPointer() )->GetBValueMap();
         mitk::BValueMapProperty::BValueMap::const_iterator it = bValMap.begin();
         unsigned int targetBVal = 0;
         while(it != bValMap.end())
             targetBVal += (it++)->first;
         targetBVal /= (float)bValMap.size()-1;
         m_Controls->m_targetBValueSpinBox->setValue(targetBVal);
 
-        m_Controls->m_HeaderSpacingX->setValue(m_SelectedImage->GetGeometry()->GetSpacing()[0]);
-        m_Controls->m_HeaderSpacingY->setValue(m_SelectedImage->GetGeometry()->GetSpacing()[1]);
-        m_Controls->m_HeaderSpacingZ->setValue(m_SelectedImage->GetGeometry()->GetSpacing()[2]);
-        m_Controls->m_HeaderOriginX->setValue(m_SelectedImage->GetGeometry()->GetOrigin()[0]);
-        m_Controls->m_HeaderOriginY->setValue(m_SelectedImage->GetGeometry()->GetOrigin()[1]);
-        m_Controls->m_HeaderOriginZ->setValue(m_SelectedImage->GetGeometry()->GetOrigin()[2]);
-        m_Controls->m_XstartBox->setMaximum(m_SelectedImage->GetGeometry()->GetExtent(0)-1);
-        m_Controls->m_YstartBox->setMaximum(m_SelectedImage->GetGeometry()->GetExtent(1)-1);
-        m_Controls->m_ZstartBox->setMaximum(m_SelectedImage->GetGeometry()->GetExtent(2)-1);
-        m_Controls->m_XendBox->setMaximum(m_SelectedImage->GetGeometry()->GetExtent(0)-1);
-        m_Controls->m_YendBox->setMaximum(m_SelectedImage->GetGeometry()->GetExtent(1)-1);
-        m_Controls->m_ZendBox->setMaximum(m_SelectedImage->GetGeometry()->GetExtent(2)-1);
-        m_Controls->m_RemoveGradientBox->setMaximum(static_cast<mitk::GradientDirectionsProperty*>( m_SelectedImage->GetProperty(mitk::DiffusionPropertyHelper::GRADIENTCONTAINERPROPERTYNAME.c_str()).GetPointer() )->GetGradientDirectionsContainer()->Size()-1);
-        m_Controls->m_ExtractGradientBox->setMaximum(static_cast<mitk::GradientDirectionsProperty*>( m_SelectedImage->GetProperty(mitk::DiffusionPropertyHelper::GRADIENTCONTAINERPROPERTYNAME.c_str()).GetPointer() )->GetGradientDirectionsContainer()->Size()-1);
+        m_Controls->m_HeaderSpacingX->setValue(image->GetGeometry()->GetSpacing()[0]);
+        m_Controls->m_HeaderSpacingY->setValue(image->GetGeometry()->GetSpacing()[1]);
+        m_Controls->m_HeaderSpacingZ->setValue(image->GetGeometry()->GetSpacing()[2]);
+        m_Controls->m_HeaderOriginX->setValue(image->GetGeometry()->GetOrigin()[0]);
+        m_Controls->m_HeaderOriginY->setValue(image->GetGeometry()->GetOrigin()[1]);
+        m_Controls->m_HeaderOriginZ->setValue(image->GetGeometry()->GetOrigin()[2]);
+        m_Controls->m_XstartBox->setMaximum(image->GetGeometry()->GetExtent(0)-1);
+        m_Controls->m_YstartBox->setMaximum(image->GetGeometry()->GetExtent(1)-1);
+        m_Controls->m_ZstartBox->setMaximum(image->GetGeometry()->GetExtent(2)-1);
+        m_Controls->m_XendBox->setMaximum(image->GetGeometry()->GetExtent(0)-1);
+        m_Controls->m_YendBox->setMaximum(image->GetGeometry()->GetExtent(1)-1);
+        m_Controls->m_ZendBox->setMaximum(image->GetGeometry()->GetExtent(2)-1);
+        m_Controls->m_RemoveGradientBox->setMaximum(static_cast<mitk::GradientDirectionsProperty*>( image->GetProperty(mitk::DiffusionPropertyHelper::GRADIENTCONTAINERPROPERTYNAME.c_str()).GetPointer() )->GetGradientDirectionsContainer()->Size()-1);
+        m_Controls->m_ExtractGradientBox->setMaximum(static_cast<mitk::GradientDirectionsProperty*>( image->GetProperty(mitk::DiffusionPropertyHelper::GRADIENTCONTAINERPROPERTYNAME.c_str()).GetPointer() )->GetGradientDirectionsContainer()->Size()-1);
     }
     else if (foundImageVolume)
     {
         for (int r=0; r<3; r++)
             for (int c=0; c<3; c++)
             {
                 QTableWidgetItem* item = m_Controls->m_MeasurementFrameTable->item(r,c);
                 delete item;
                 item = new QTableWidgetItem();
                 m_Controls->m_MeasurementFrameTable->setItem(r,c,item);
             }
 
-        m_Controls->m_HeaderSpacingX->setValue(m_SelectedImage->GetGeometry()->GetSpacing()[0]);
-        m_Controls->m_HeaderSpacingY->setValue(m_SelectedImage->GetGeometry()->GetSpacing()[1]);
-        m_Controls->m_HeaderSpacingZ->setValue(m_SelectedImage->GetGeometry()->GetSpacing()[2]);
-        m_Controls->m_HeaderOriginX->setValue(m_SelectedImage->GetGeometry()->GetOrigin()[0]);
-        m_Controls->m_HeaderOriginY->setValue(m_SelectedImage->GetGeometry()->GetOrigin()[1]);
-        m_Controls->m_HeaderOriginZ->setValue(m_SelectedImage->GetGeometry()->GetOrigin()[2]);
-        m_Controls->m_XstartBox->setMaximum(m_SelectedImage->GetGeometry()->GetExtent(0)-1);
-        m_Controls->m_YstartBox->setMaximum(m_SelectedImage->GetGeometry()->GetExtent(1)-1);
-        m_Controls->m_ZstartBox->setMaximum(m_SelectedImage->GetGeometry()->GetExtent(2)-1);
-        m_Controls->m_XendBox->setMaximum(m_SelectedImage->GetGeometry()->GetExtent(0)-1);
-        m_Controls->m_YendBox->setMaximum(m_SelectedImage->GetGeometry()->GetExtent(1)-1);
-        m_Controls->m_ZendBox->setMaximum(m_SelectedImage->GetGeometry()->GetExtent(2)-1);
-
-        AccessFixedDimensionByItk(m_SelectedImage, TemplatedUpdateGui,3);
+        m_Controls->m_HeaderSpacingX->setValue(image->GetGeometry()->GetSpacing()[0]);
+        m_Controls->m_HeaderSpacingY->setValue(image->GetGeometry()->GetSpacing()[1]);
+        m_Controls->m_HeaderSpacingZ->setValue(image->GetGeometry()->GetSpacing()[2]);
+        m_Controls->m_HeaderOriginX->setValue(image->GetGeometry()->GetOrigin()[0]);
+        m_Controls->m_HeaderOriginY->setValue(image->GetGeometry()->GetOrigin()[1]);
+        m_Controls->m_HeaderOriginZ->setValue(image->GetGeometry()->GetOrigin()[2]);
+        m_Controls->m_XstartBox->setMaximum(image->GetGeometry()->GetExtent(0)-1);
+        m_Controls->m_YstartBox->setMaximum(image->GetGeometry()->GetExtent(1)-1);
+        m_Controls->m_ZstartBox->setMaximum(image->GetGeometry()->GetExtent(2)-1);
+        m_Controls->m_XendBox->setMaximum(image->GetGeometry()->GetExtent(0)-1);
+        m_Controls->m_YendBox->setMaximum(image->GetGeometry()->GetExtent(1)-1);
+        m_Controls->m_ZendBox->setMaximum(image->GetGeometry()->GetExtent(2)-1);
+
+        AccessFixedDimensionByItk(image, TemplatedUpdateGui,3);
     }
     else
     {
         for (int r=0; r<3; r++)
             for (int c=0; c<3; c++)
             {
                 {
                     QTableWidgetItem* item = m_Controls->m_MeasurementFrameTable->item(r,c);
                     delete item;
                     item = new QTableWidgetItem();
                     m_Controls->m_MeasurementFrameTable->setItem(r,c,item);
                 }
                 {
                     QTableWidgetItem* item = m_Controls->m_DirectionMatrixTable->item(r,c);
                     delete item;
                     item = new QTableWidgetItem();
                     m_Controls->m_DirectionMatrixTable->setItem(r,c,item);
                 }
             }
-
-        m_Controls->m_DiffusionImageLabel->setText("<font color='red'>mandatory</font>");
-        m_Controls->m_InputData->setTitle("Please Select Input Data");
     }
 }
 
 void QmitkPreprocessingView::Activated()
 {
     QmitkFunctionality::Activated();
 }
 
 void QmitkPreprocessingView::Deactivated()
 {
     QmitkFunctionality::Deactivated();
 }
 
 void QmitkPreprocessingView::DoHalfSphereGradientDirections()
 {
+    mitk::DataNode::Pointer node = m_Controls->m_SelctedImageComboBox->GetSelectedNode();
+    if (node.IsNull())
+        return;
+    mitk::Image::Pointer image = dynamic_cast<mitk::Image*>(node->GetData());
 
-    mitk::Image::Pointer newDwi = m_SelectedImage->Clone();
+    mitk::Image::Pointer newDwi = image->Clone();
     GradientDirectionContainerType::Pointer gradientContainer =   static_cast<mitk::GradientDirectionsProperty*>( newDwi->GetProperty(mitk::DiffusionPropertyHelper::GRADIENTCONTAINERPROPERTYNAME.c_str()).GetPointer() )->GetGradientDirectionsContainer();
 
     for (unsigned int j=0; j<gradientContainer->Size(); j++)
         if (gradientContainer->at(j)[0]<0)
             gradientContainer->at(j) = -gradientContainer->at(j);
 
     newDwi->SetProperty( mitk::DiffusionPropertyHelper::GRADIENTCONTAINERPROPERTYNAME.c_str(), mitk::GradientDirectionsProperty::New( gradientContainer ) );
     mitk::DiffusionPropertyHelper propertyHelper( newDwi );
     propertyHelper.InitializeImage();
 
     mitk::DataNode::Pointer imageNode = mitk::DataNode::New();
     imageNode->SetData( newDwi );
-    QString name = m_SelectedDiffusionNodes.back()->GetName().c_str();
+    QString name = node->GetName().c_str();
     imageNode->SetName((name+"_halfsphere").toStdString().c_str());
-    GetDefaultDataStorage()->Add(imageNode, m_SelectedDiffusionNodes.back());
+    GetDefaultDataStorage()->Add(imageNode, node);
 }
 
 void QmitkPreprocessingView::DoApplyMesurementFrame()
 {
-    bool isDiffusionImage( mitk::DiffusionPropertyHelper::IsDiffusionWeightedImage( dynamic_cast<mitk::Image *>(m_SelectedImageNode->GetData())) );
+    mitk::DataNode::Pointer node = m_Controls->m_SelctedImageComboBox->GetSelectedNode();
+    if (node.IsNull())
+        return;
+    mitk::Image::Pointer image = dynamic_cast<mitk::Image*>(node->GetData());
+
+    bool isDiffusionImage( mitk::DiffusionPropertyHelper::IsDiffusionWeightedImage(image) );
     if ( !isDiffusionImage )
         return;
 
     vnl_matrix_fixed< double, 3, 3 > mf;
     for (int r=0; r<3; r++)
         for (int c=0; c<3; c++)
         {
             QTableWidgetItem* item = m_Controls->m_MeasurementFrameTable->item(r,c);
             if (!item)
                 return;
             mf[r][c] = item->text().toDouble();
         }
 
-    mitk::Image::Pointer newDwi = m_SelectedImage->Clone();
+    mitk::Image::Pointer newDwi = image->Clone();
     newDwi->SetProperty( mitk::DiffusionPropertyHelper::MEASUREMENTFRAMEPROPERTYNAME.c_str(), mitk::MeasurementFrameProperty::New( mf ) );
     mitk::DiffusionPropertyHelper propertyHelper( newDwi );
     propertyHelper.InitializeImage();
 
     mitk::DataNode::Pointer imageNode = mitk::DataNode::New();
     imageNode->SetData( newDwi );
-    QString name = m_SelectedDiffusionNodes.back()->GetName().c_str();
+    QString name = node->GetName().c_str();
     imageNode->SetName((name+"_new-MF").toStdString().c_str());
-    GetDefaultDataStorage()->Add(imageNode, m_SelectedDiffusionNodes.back());
+    GetDefaultDataStorage()->Add(imageNode, node);
 }
 
 void QmitkPreprocessingView::DoShowGradientDirections()
 {
-    bool isDiffusionImage( mitk::DiffusionPropertyHelper::IsDiffusionWeightedImage( dynamic_cast<mitk::Image *>(m_SelectedImageNode->GetData())) );
+    mitk::DataNode::Pointer node = m_Controls->m_SelctedImageComboBox->GetSelectedNode();
+    if (node.IsNull())
+        return;
+    mitk::Image::Pointer image = dynamic_cast<mitk::Image*>(node->GetData());
+
+    bool isDiffusionImage( mitk::DiffusionPropertyHelper::IsDiffusionWeightedImage(image) );
     if ( !isDiffusionImage )
         return;
 
     int maxIndex = 0;
-    unsigned int maxSize = m_SelectedImage->GetDimension(0);
-    if (maxSize<m_SelectedImage->GetDimension(1))
+    unsigned int maxSize = image->GetDimension(0);
+    if (maxSize<image->GetDimension(1))
     {
-        maxSize = m_SelectedImage->GetDimension(1);
+        maxSize = image->GetDimension(1);
         maxIndex = 1;
     }
-    if (maxSize<m_SelectedImage->GetDimension(2))
+    if (maxSize<image->GetDimension(2))
     {
-        maxSize = m_SelectedImage->GetDimension(2);
+        maxSize = image->GetDimension(2);
         maxIndex = 2;
     }
 
-    mitk::Point3D origin = m_SelectedImage->GetGeometry()->GetOrigin();
+    mitk::Point3D origin = image->GetGeometry()->GetOrigin();
     mitk::PointSet::Pointer originSet = mitk::PointSet::New();
 
     typedef mitk::BValueMapProperty::BValueMap BValueMap;
     typedef mitk::BValueMapProperty::BValueMap::iterator BValueMapIterator;
-    BValueMap bValMap =  static_cast<mitk::BValueMapProperty*>(m_SelectedImage->GetProperty(mitk::DiffusionPropertyHelper::BVALUEMAPPROPERTYNAME.c_str()).GetPointer() )->GetBValueMap();
+    BValueMap bValMap =  static_cast<mitk::BValueMapProperty*>(image->GetProperty(mitk::DiffusionPropertyHelper::BVALUEMAPPROPERTYNAME.c_str()).GetPointer() )->GetBValueMap();
 
-    GradientDirectionContainerType::Pointer gradientContainer = static_cast<mitk::GradientDirectionsProperty*>( m_SelectedImage->GetProperty(mitk::DiffusionPropertyHelper::GRADIENTCONTAINERPROPERTYNAME.c_str()).GetPointer() )->GetGradientDirectionsContainer();
-    mitk::BaseGeometry::Pointer geometry = m_SelectedImage->GetGeometry();
+    GradientDirectionContainerType::Pointer gradientContainer = static_cast<mitk::GradientDirectionsProperty*>( image->GetProperty(mitk::DiffusionPropertyHelper::GRADIENTCONTAINERPROPERTYNAME.c_str()).GetPointer() )->GetGradientDirectionsContainer();
+    mitk::BaseGeometry::Pointer geometry = image->GetGeometry();
     int shellCount = 1;
     for(BValueMapIterator it = bValMap.begin(); it!=bValMap.end(); ++it)
     {
         mitk::PointSet::Pointer pointset = mitk::PointSet::New();
         for (unsigned int j=0; j<it->second.size(); j++)
         {
             mitk::Point3D ip;
             vnl_vector_fixed< double, 3 > v = gradientContainer->at(it->second[j]);
-            MITK_INFO << v;
             if (v.magnitude()>mitk::eps)
             {
-                ip[0] = v[0]*maxSize*geometry->GetSpacing()[maxIndex]/2 + origin[0]-0.5*geometry->GetSpacing()[0] + geometry->GetSpacing()[0]*m_SelectedImage->GetDimension(0)/2;
-                ip[1] = v[1]*maxSize*geometry->GetSpacing()[maxIndex]/2 + origin[1]-0.5*geometry->GetSpacing()[1] + geometry->GetSpacing()[1]*m_SelectedImage->GetDimension(1)/2;
-                ip[2] = v[2]*maxSize*geometry->GetSpacing()[maxIndex]/2 + origin[2]-0.5*geometry->GetSpacing()[2] + geometry->GetSpacing()[2]*m_SelectedImage->GetDimension(2)/2;
+                ip[0] = v[0]*maxSize*geometry->GetSpacing()[maxIndex]/2 + origin[0]-0.5*geometry->GetSpacing()[0] + geometry->GetSpacing()[0]*image->GetDimension(0)/2;
+                ip[1] = v[1]*maxSize*geometry->GetSpacing()[maxIndex]/2 + origin[1]-0.5*geometry->GetSpacing()[1] + geometry->GetSpacing()[1]*image->GetDimension(1)/2;
+                ip[2] = v[2]*maxSize*geometry->GetSpacing()[maxIndex]/2 + origin[2]-0.5*geometry->GetSpacing()[2] + geometry->GetSpacing()[2]*image->GetDimension(2)/2;
 
                 pointset->InsertPoint(j, ip);
             }
             else if (originSet->IsEmpty())
             {
-                ip[0] = v[0]*maxSize*geometry->GetSpacing()[maxIndex]/2 + origin[0]-0.5*geometry->GetSpacing()[0] + geometry->GetSpacing()[0]*m_SelectedImage->GetDimension(0)/2;
-                ip[1] = v[1]*maxSize*geometry->GetSpacing()[maxIndex]/2 + origin[1]-0.5*geometry->GetSpacing()[1] + geometry->GetSpacing()[1]*m_SelectedImage->GetDimension(1)/2;
-                ip[2] = v[2]*maxSize*geometry->GetSpacing()[maxIndex]/2 + origin[2]-0.5*geometry->GetSpacing()[2] + geometry->GetSpacing()[2]*m_SelectedImage->GetDimension(2)/2;
+                ip[0] = v[0]*maxSize*geometry->GetSpacing()[maxIndex]/2 + origin[0]-0.5*geometry->GetSpacing()[0] + geometry->GetSpacing()[0]*image->GetDimension(0)/2;
+                ip[1] = v[1]*maxSize*geometry->GetSpacing()[maxIndex]/2 + origin[1]-0.5*geometry->GetSpacing()[1] + geometry->GetSpacing()[1]*image->GetDimension(1)/2;
+                ip[2] = v[2]*maxSize*geometry->GetSpacing()[maxIndex]/2 + origin[2]-0.5*geometry->GetSpacing()[2] + geometry->GetSpacing()[2]*image->GetDimension(2)/2;
 
                 originSet->InsertPoint(j, ip);
             }
         }
         if (it->first<mitk::eps)
             continue;
 
         // add shell to datastorage
-        mitk::DataNode::Pointer node = mitk::DataNode::New();
-        node->SetData(pointset);
-        QString name = m_SelectedDiffusionNodes.front()->GetName().c_str();
+        mitk::DataNode::Pointer newNode = mitk::DataNode::New();
+        newNode->SetData(pointset);
+        QString name = node->GetName().c_str();
         name += "_Shell_";
         name += QString::number(it->first);
-        node->SetName(name.toStdString().c_str());
-        node->SetProperty("pointsize", mitk::FloatProperty::New((float)maxSize/50));
+        newNode->SetName(name.toStdString().c_str());
+        newNode->SetProperty("pointsize", mitk::FloatProperty::New((float)maxSize/50));
         int b0 = shellCount%2;
         int b1 = 0;
         int b2 = 0;
         if (shellCount>4)
             b2 = 1;
         if (shellCount%4 >= 2)
             b1 = 1;
 
-        node->SetProperty("color", mitk::ColorProperty::New(b2, b1, b0));
-        GetDefaultDataStorage()->Add(node, m_SelectedDiffusionNodes.front());
+        newNode->SetProperty("color", mitk::ColorProperty::New(b2, b1, b0));
+        GetDefaultDataStorage()->Add(newNode, node);
         shellCount++;
     }
 
     // add origin to datastorage
-    mitk::DataNode::Pointer node = mitk::DataNode::New();
-    node->SetData(originSet);
-    QString name = m_SelectedDiffusionNodes.front()->GetName().c_str();
+    mitk::DataNode::Pointer newNode = mitk::DataNode::New();
+    newNode->SetData(originSet);
+    QString name = node->GetName().c_str();
     name += "_Origin";
-    node->SetName(name.toStdString().c_str());
-    node->SetProperty("pointsize", mitk::FloatProperty::New((float)maxSize/50));
-    node->SetProperty("color", mitk::ColorProperty::New(1,1,1));
-    GetDefaultDataStorage()->Add(node, m_SelectedDiffusionNodes.front());
+    newNode->SetName(name.toStdString().c_str());
+    newNode->SetProperty("pointsize", mitk::FloatProperty::New((float)maxSize/50));
+    newNode->SetProperty("color", mitk::ColorProperty::New(1,1,1));
+    GetDefaultDataStorage()->Add(newNode, node);
 }
 
 void QmitkPreprocessingView::DoReduceGradientDirections()
 {
-    bool isDiffusionImage( mitk::DiffusionPropertyHelper::IsDiffusionWeightedImage( dynamic_cast<mitk::Image *>(m_SelectedImageNode->GetData())) );
+    mitk::DataNode::Pointer node = m_Controls->m_SelctedImageComboBox->GetSelectedNode();
+    if (node.IsNull())
+        return;
+    mitk::Image::Pointer image = dynamic_cast<mitk::Image*>(node->GetData());
+
+    bool isDiffusionImage( mitk::DiffusionPropertyHelper::IsDiffusionWeightedImage(image) );
     if ( !isDiffusionImage )
         return;
 
     typedef itk::ElectrostaticRepulsionDiffusionGradientReductionFilter<DiffusionPixelType, DiffusionPixelType> FilterType;
     typedef mitk::BValueMapProperty::BValueMap BValueMap;
 
     // GetShellSelection from GUI
     BValueMap shellSlectionMap;
-    BValueMap originalShellMap = static_cast<mitk::BValueMapProperty*>(m_SelectedImage->GetProperty(mitk::DiffusionPropertyHelper::BVALUEMAPPROPERTYNAME.c_str()).GetPointer() )->GetBValueMap();
+    BValueMap originalShellMap = static_cast<mitk::BValueMapProperty*>(image->GetProperty(mitk::DiffusionPropertyHelper::BVALUEMAPPROPERTYNAME.c_str()).GetPointer() )->GetBValueMap();
     std::vector<unsigned int> newNumGradientDirections;
     int shellCounter = 0;
 
-    QString name = m_SelectedDiffusionNodes.front()->GetName().c_str();
+    QString name = node->GetName().c_str();
     for (int i=0; i<m_Controls->m_B_ValueMap_TableWidget->rowCount(); i++)
     {
         double BValue = m_Controls->m_B_ValueMap_TableWidget->item(i,0)->text().toDouble();
         shellSlectionMap[BValue] = originalShellMap[BValue];
         unsigned int num = m_Controls->m_B_ValueMap_TableWidget->item(i,1)->text().toUInt();
         newNumGradientDirections.push_back(num);
         name += "_";
         name += QString::number(num);
         shellCounter++;
     }
 
     if (newNumGradientDirections.empty())
         return;
 
-    GradientDirectionContainerType::Pointer gradientContainer = static_cast<mitk::GradientDirectionsProperty*>( m_SelectedImage->GetProperty(mitk::DiffusionPropertyHelper::GRADIENTCONTAINERPROPERTYNAME.c_str()).GetPointer() )->GetGradientDirectionsContainer();
+    GradientDirectionContainerType::Pointer gradientContainer = static_cast<mitk::GradientDirectionsProperty*>( image->GetProperty(mitk::DiffusionPropertyHelper::GRADIENTCONTAINERPROPERTYNAME.c_str()).GetPointer() )->GetGradientDirectionsContainer();
 
     ItkDwiType::Pointer itkVectorImagePointer = ItkDwiType::New();
-    mitk::CastToItkImage(m_SelectedImage, itkVectorImagePointer);
+    mitk::CastToItkImage(image, itkVectorImagePointer);
 
     FilterType::Pointer filter = FilterType::New();
     filter->SetInput( itkVectorImagePointer );
     filter->SetOriginalGradientDirections(gradientContainer);
     filter->SetNumGradientDirections(newNumGradientDirections);
     filter->SetOriginalBValueMap(originalShellMap);
     filter->SetShellSelectionBValueMap(shellSlectionMap);
     filter->Update();
 
-    mitk::Image::Pointer image = mitk::GrabItkImageMemory( filter->GetOutput() );
-    image->SetProperty( mitk::DiffusionPropertyHelper::GRADIENTCONTAINERPROPERTYNAME.c_str(), mitk::GradientDirectionsProperty::New( filter->GetGradientDirections() ) );
-    image->SetProperty( mitk::DiffusionPropertyHelper::MEASUREMENTFRAMEPROPERTYNAME.c_str(), mitk::MeasurementFrameProperty::New( static_cast<mitk::MeasurementFrameProperty*>(m_SelectedImage->GetProperty(mitk::DiffusionPropertyHelper::MEASUREMENTFRAMEPROPERTYNAME.c_str()).GetPointer() )->GetMeasurementFrame() ) );
-    image->SetProperty( mitk::DiffusionPropertyHelper::REFERENCEBVALUEPROPERTYNAME.c_str(), mitk::FloatProperty::New( static_cast<mitk::FloatProperty*>(m_SelectedImage->GetProperty(mitk::DiffusionPropertyHelper::REFERENCEBVALUEPROPERTYNAME.c_str()).GetPointer() )->GetValue() ) );
-    mitk::DiffusionPropertyHelper propertyHelper( image );
+    mitk::Image::Pointer newImage = mitk::GrabItkImageMemory( filter->GetOutput() );
+    newImage->SetProperty( mitk::DiffusionPropertyHelper::GRADIENTCONTAINERPROPERTYNAME.c_str(), mitk::GradientDirectionsProperty::New( filter->GetGradientDirections() ) );
+    newImage->SetProperty( mitk::DiffusionPropertyHelper::MEASUREMENTFRAMEPROPERTYNAME.c_str(), mitk::MeasurementFrameProperty::New( static_cast<mitk::MeasurementFrameProperty*>(image->GetProperty(mitk::DiffusionPropertyHelper::MEASUREMENTFRAMEPROPERTYNAME.c_str()).GetPointer() )->GetMeasurementFrame() ) );
+    newImage->SetProperty( mitk::DiffusionPropertyHelper::REFERENCEBVALUEPROPERTYNAME.c_str(), mitk::FloatProperty::New( static_cast<mitk::FloatProperty*>(image->GetProperty(mitk::DiffusionPropertyHelper::REFERENCEBVALUEPROPERTYNAME.c_str()).GetPointer() )->GetValue() ) );
+    mitk::DiffusionPropertyHelper propertyHelper( newImage );
     propertyHelper.InitializeImage();
 
 
     mitk::DataNode::Pointer imageNode = mitk::DataNode::New();
-    imageNode->SetData( image );
+    imageNode->SetData( newImage );
 
     imageNode->SetName(name.toStdString().c_str());
-    GetDefaultDataStorage()->Add(imageNode, m_SelectedDiffusionNodes.back());
+    GetDefaultDataStorage()->Add(imageNode, node);
 }
 
 void QmitkPreprocessingView::MergeDwis()
 {
     typedef mitk::GradientDirectionsProperty::GradientDirectionsContainerType    GradientContainerType;
 
-    if (m_SelectedDiffusionNodes.size()<2)
+    mitk::DataNode::Pointer node = m_Controls->m_SelctedImageComboBox->GetSelectedNode();
+    if (node.IsNull())
+        return;
+    mitk::Image::Pointer image = dynamic_cast<mitk::Image*>(node->GetData());
+
+    bool isDiffusionImage( mitk::DiffusionPropertyHelper::IsDiffusionWeightedImage(image) );
+    if ( !isDiffusionImage )
+        return;
+
+    mitk::DataNode::Pointer node2 = m_Controls->m_MergeDwiBox->GetSelectedNode();
+    if (node2.IsNull())
         return;
+    mitk::Image::Pointer image2 = dynamic_cast<mitk::Image*>(node2->GetData());
 
     typedef itk::VectorImage<DiffusionPixelType,3>                  DwiImageType;
     typedef DwiImageType::PixelType                        DwiPixelType;
     typedef DwiImageType::RegionType                       DwiRegionType;
     typedef std::vector< DwiImageType::Pointer >  DwiImageContainerType;
 
     typedef std::vector< GradientContainerType::Pointer >  GradientListContainerType;
 
     DwiImageContainerType       imageContainer;
     GradientListContainerType   gradientListContainer;
     std::vector< double >       bValueContainer;
 
-    QString name = m_SelectedDiffusionNodes.front()->GetName().c_str();
-    for (unsigned int i=0; i<m_SelectedDiffusionNodes.size(); i++)
+    QString name = "";
     {
-        mitk::Image::Pointer dwi = dynamic_cast< mitk::Image* >( m_SelectedDiffusionNodes.at(i)->GetData() );
-        if ( dwi.IsNotNull() )
-        {
-            ItkDwiType::Pointer itkVectorImagePointer = ItkDwiType::New();
-            mitk::CastToItkImage(dwi, itkVectorImagePointer);
+        ItkDwiType::Pointer itkVectorImagePointer = ItkDwiType::New();
+        mitk::CastToItkImage(image, itkVectorImagePointer);
 
-            imageContainer.push_back( itkVectorImagePointer );
-            gradientListContainer.push_back( static_cast<mitk::GradientDirectionsProperty*>( dwi->GetProperty(mitk::DiffusionPropertyHelper::GRADIENTCONTAINERPROPERTYNAME.c_str()).GetPointer() )->GetGradientDirectionsContainer() );
-            bValueContainer.push_back( static_cast<mitk::FloatProperty*>(dwi->GetProperty(mitk::DiffusionPropertyHelper::REFERENCEBVALUEPROPERTYNAME.c_str()).GetPointer() )->GetValue() );
-            if (i>0)
-            {
-                name += "+";
-                name += m_SelectedDiffusionNodes.at(i)->GetName().c_str();
-            }
-        }
+        imageContainer.push_back( itkVectorImagePointer );
+        gradientListContainer.push_back( static_cast<mitk::GradientDirectionsProperty*>( image->GetProperty(mitk::DiffusionPropertyHelper::GRADIENTCONTAINERPROPERTYNAME.c_str()).GetPointer() )->GetGradientDirectionsContainer() );
+        bValueContainer.push_back( static_cast<mitk::FloatProperty*>(image->GetProperty(mitk::DiffusionPropertyHelper::REFERENCEBVALUEPROPERTYNAME.c_str()).GetPointer() )->GetValue() );
+        name += node->GetName().c_str();
+    }
+
+    {
+        ItkDwiType::Pointer itkVectorImagePointer = ItkDwiType::New();
+        mitk::CastToItkImage(image2, itkVectorImagePointer);
+
+        imageContainer.push_back( itkVectorImagePointer );
+        gradientListContainer.push_back( static_cast<mitk::GradientDirectionsProperty*>( image2->GetProperty(mitk::DiffusionPropertyHelper::GRADIENTCONTAINERPROPERTYNAME.c_str()).GetPointer() )->GetGradientDirectionsContainer() );
+        bValueContainer.push_back( static_cast<mitk::FloatProperty*>(image2->GetProperty(mitk::DiffusionPropertyHelper::REFERENCEBVALUEPROPERTYNAME.c_str()).GetPointer() )->GetValue() );
+        name += "+";
+        name += node2->GetName().c_str();
     }
 
     typedef itk::MergeDiffusionImagesFilter<short> FilterType;
     FilterType::Pointer filter = FilterType::New();
     filter->SetImageVolumes(imageContainer);
     filter->SetGradientLists(gradientListContainer);
     filter->SetBValues(bValueContainer);
     filter->Update();
 
     vnl_matrix_fixed< double, 3, 3 > mf; mf.set_identity();
-    mitk::Image::Pointer image = mitk::GrabItkImageMemory( filter->GetOutput() );
+    mitk::Image::Pointer newImage = mitk::GrabItkImageMemory( filter->GetOutput() );
 
-    image->SetProperty( mitk::DiffusionPropertyHelper::GRADIENTCONTAINERPROPERTYNAME.c_str(), mitk::GradientDirectionsProperty::New( filter->GetOutputGradients() ) );
-    image->SetProperty( mitk::DiffusionPropertyHelper::MEASUREMENTFRAMEPROPERTYNAME.c_str(), mitk::MeasurementFrameProperty::New( mf ) );
-    image->SetProperty( mitk::DiffusionPropertyHelper::REFERENCEBVALUEPROPERTYNAME.c_str(), mitk::FloatProperty::New( filter->GetB_Value() ) );
-    mitk::DiffusionPropertyHelper propertyHelper( image );
+    newImage->SetProperty( mitk::DiffusionPropertyHelper::GRADIENTCONTAINERPROPERTYNAME.c_str(), mitk::GradientDirectionsProperty::New( filter->GetOutputGradients() ) );
+    newImage->SetProperty( mitk::DiffusionPropertyHelper::MEASUREMENTFRAMEPROPERTYNAME.c_str(), mitk::MeasurementFrameProperty::New( mf ) );
+    newImage->SetProperty( mitk::DiffusionPropertyHelper::REFERENCEBVALUEPROPERTYNAME.c_str(), mitk::FloatProperty::New( filter->GetB_Value() ) );
+    mitk::DiffusionPropertyHelper propertyHelper( newImage );
     propertyHelper.InitializeImage();
 
     mitk::DataNode::Pointer imageNode = mitk::DataNode::New();
-    imageNode->SetData( image );
+    imageNode->SetData( newImage );
     imageNode->SetName(name.toStdString().c_str());
     GetDefaultDataStorage()->Add(imageNode);
 }
 
 void QmitkPreprocessingView::ExtractB0()
 {
-    typedef mitk::GradientDirectionsProperty::GradientDirectionsContainerType    GradientContainerType;
+    mitk::DataNode::Pointer node = m_Controls->m_SelctedImageComboBox->GetSelectedNode();
+    if (node.IsNull())
+        return;
+    mitk::Image::Pointer image = dynamic_cast<mitk::Image*>(node->GetData());
 
-    int nrFiles = m_SelectedDiffusionNodes.size();
-    if (!nrFiles) return;
+    bool isDiffusionImage( mitk::DiffusionPropertyHelper::IsDiffusionWeightedImage(image) );
+    if ( !isDiffusionImage )
+        return;
+
+    typedef mitk::GradientDirectionsProperty::GradientDirectionsContainerType    GradientContainerType;
 
     // call the extraction withou averaging if the check-box is checked
     if( this->m_Controls->m_CheckExtractAll->isChecked() )
     {
         DoExtractBOWithoutAveraging();
         return;
     }
 
-    mitk::DataStorage::SetOfObjects::const_iterator itemiter( m_SelectedDiffusionNodes.begin() );
-    mitk::DataStorage::SetOfObjects::const_iterator itemiterend( m_SelectedDiffusionNodes.end() );
-
-    std::vector<mitk::DataNode::Pointer> nodes;
-    while ( itemiter != itemiterend ) // for all items
-    {
-
-        mitk::Image* vols =
-                static_cast<mitk::Image*>(
-                    (*itemiter)->GetData());
-
-        std::string nodename;
-        (*itemiter)->GetStringProperty("name", nodename);
-
-        ItkDwiType::Pointer itkVectorImagePointer = ItkDwiType::New();
-        mitk::CastToItkImage(vols, itkVectorImagePointer);
-
-        // Extract image using found index
-        typedef itk::B0ImageExtractionImageFilter<short, short> FilterType;
-        FilterType::Pointer filter = FilterType::New();
-        filter->SetInput( itkVectorImagePointer );
-        filter->SetDirections( static_cast<mitk::GradientDirectionsProperty*>( vols->GetProperty(mitk::DiffusionPropertyHelper::GRADIENTCONTAINERPROPERTYNAME.c_str()).GetPointer() )->GetGradientDirectionsContainer() );
-        filter->Update();
+    ItkDwiType::Pointer itkVectorImagePointer = ItkDwiType::New();
+    mitk::CastToItkImage(image, itkVectorImagePointer);
 
-        mitk::Image::Pointer mitkImage = mitk::Image::New();
-        mitkImage->InitializeByItk( filter->GetOutput() );
-        mitkImage->SetVolume( filter->GetOutput()->GetBufferPointer() );
-        mitk::DataNode::Pointer node=mitk::DataNode::New();
-        node->SetData( mitkImage );
-        node->SetProperty( "name", mitk::StringProperty::New(nodename + "_B0"));
+    // Extract image using found index
+    typedef itk::B0ImageExtractionImageFilter<short, short> FilterType;
+    FilterType::Pointer filter = FilterType::New();
+    filter->SetInput( itkVectorImagePointer );
+    filter->SetDirections( static_cast<mitk::GradientDirectionsProperty*>( image->GetProperty(mitk::DiffusionPropertyHelper::GRADIENTCONTAINERPROPERTYNAME.c_str()).GetPointer() )->GetGradientDirectionsContainer() );
+    filter->Update();
 
-        GetDefaultDataStorage()->Add(node, (*itemiter));
+    mitk::Image::Pointer mitkImage = mitk::Image::New();
+    mitkImage->InitializeByItk( filter->GetOutput() );
+    mitkImage->SetVolume( filter->GetOutput()->GetBufferPointer() );
+    mitk::DataNode::Pointer newNode=mitk::DataNode::New();
+    newNode->SetData( mitkImage );
+    newNode->SetProperty( "name", mitk::StringProperty::New(node->GetName() + "_B0"));
 
-        ++itemiter;
-    }
+    GetDefaultDataStorage()->Add(newNode, node);
 }
 
 void QmitkPreprocessingView::DoExtractBOWithoutAveraging()
 {
-    // typedefs
-    typedef mitk::GradientDirectionsProperty::GradientDirectionsContainerType    GradientContainerType;
-    typedef itk::B0ImageExtractionToSeparateImageFilter< short, short> FilterType;
-
-    // check number of selected objects, return if empty
-    int nrFiles = m_SelectedDiffusionNodes.size();
-    if (!nrFiles)
+    mitk::DataNode::Pointer node = m_Controls->m_SelctedImageComboBox->GetSelectedNode();
+    if (node.IsNull())
         return;
+    mitk::Image::Pointer image = dynamic_cast<mitk::Image*>(node->GetData());
 
-    mitk::DataStorage::SetOfObjects::const_iterator itemiter( m_SelectedDiffusionNodes.begin() );
-    mitk::DataStorage::SetOfObjects::const_iterator itemiterend( m_SelectedDiffusionNodes.end() );
-
-    while ( itemiter != itemiterend ) // for all items
-    {
-        mitk::Image* vols =
-                static_cast<mitk::Image*>(
-                    (*itemiter)->GetData());
+    bool isDiffusionImage( mitk::DiffusionPropertyHelper::IsDiffusionWeightedImage(image) );
+    if ( !isDiffusionImage )
+        return;
 
-        std::string nodename;
-        (*itemiter)->GetStringProperty("name", nodename);
+    // typedefs
+    typedef mitk::GradientDirectionsProperty::GradientDirectionsContainerType    GradientContainerType;
+    typedef itk::B0ImageExtractionToSeparateImageFilter< short, short> FilterType;
 
-        ItkDwiType::Pointer itkVectorImagePointer = ItkDwiType::New();
-        mitk::CastToItkImage(vols, itkVectorImagePointer);
+    ItkDwiType::Pointer itkVectorImagePointer = ItkDwiType::New();
+    mitk::CastToItkImage(image, itkVectorImagePointer);
 
-        // Extract image using found index
-        FilterType::Pointer filter = FilterType::New();
-        filter->SetInput( itkVectorImagePointer );
-        filter->SetDirections( static_cast<mitk::GradientDirectionsProperty*>( vols->GetProperty(mitk::DiffusionPropertyHelper::GRADIENTCONTAINERPROPERTYNAME.c_str()).GetPointer() )->GetGradientDirectionsContainer() );
-        filter->Update();
+    // Extract image using found index
+    FilterType::Pointer filter = FilterType::New();
+    filter->SetInput( itkVectorImagePointer );
+    filter->SetDirections( static_cast<mitk::GradientDirectionsProperty*>( image->GetProperty(mitk::DiffusionPropertyHelper::GRADIENTCONTAINERPROPERTYNAME.c_str()).GetPointer() )->GetGradientDirectionsContainer() );
+    filter->Update();
 
-        mitk::Image::Pointer mitkImage = mitk::Image::New();
-        mitkImage->InitializeByItk( filter->GetOutput() );
-        mitkImage->SetImportChannel( filter->GetOutput()->GetBufferPointer() );
-        mitk::DataNode::Pointer node=mitk::DataNode::New();
-        node->SetData( mitkImage );
-        node->SetProperty( "name", mitk::StringProperty::New(nodename + "_B0_ALL"));
+    mitk::Image::Pointer mitkImage = mitk::Image::New();
+    mitkImage->InitializeByItk( filter->GetOutput() );
+    mitkImage->SetImportChannel( filter->GetOutput()->GetBufferPointer() );
+    mitk::DataNode::Pointer newNode=mitk::DataNode::New();
+    newNode->SetData( mitkImage );
+    newNode->SetProperty( "name", mitk::StringProperty::New(node->GetName() + "_B0_ALL"));
 
-        GetDefaultDataStorage()->Add(node, (*itemiter));
+    GetDefaultDataStorage()->Add(newNode, node);
 
-        /*A reinitialization is needed to access the time channels via the ImageNavigationController
+    /*A reinitialization is needed to access the time channels via the ImageNavigationController
     The Global-Geometry can not recognize the time channel without a re-init.
     (for a new selection in datamanger a automatically updated of the Global-Geometry should be done - if it contains the time channel)*/
-        mitk::RenderingManager::GetInstance()->InitializeViews(node->GetData()->GetTimeGeometry(),mitk::RenderingManager::REQUEST_UPDATE_ALL, true);
-
-        ++itemiter;
-    }
+    mitk::RenderingManager::GetInstance()->InitializeViews(newNode->GetData()->GetTimeGeometry(),mitk::RenderingManager::REQUEST_UPDATE_ALL, true);
 }
 
 void QmitkPreprocessingView::AverageGradients()
 {
-    int nrFiles = m_SelectedDiffusionNodes.size();
-    if (!nrFiles) return;
-
-    mitk::DataStorage::SetOfObjects::const_iterator itemiter( m_SelectedDiffusionNodes.begin() );
-    mitk::DataStorage::SetOfObjects::const_iterator itemiterend( m_SelectedDiffusionNodes.end() );
-
-    while ( itemiter != itemiterend ) // for all items
-    {
-        mitk::Image* mitkDwi =
-                static_cast<mitk::Image*>(
-                    (*itemiter)->GetData());
+    mitk::DataNode::Pointer node = m_Controls->m_SelctedImageComboBox->GetSelectedNode();
+    if (node.IsNull())
+        return;
+    mitk::Image::Pointer image = dynamic_cast<mitk::Image*>(node->GetData());
 
-        mitk::Image::Pointer newDwi = mitkDwi->Clone();
-        newDwi->SetPropertyList(mitkDwi->GetPropertyList()->Clone());
+    bool isDiffusionImage( mitk::DiffusionPropertyHelper::IsDiffusionWeightedImage(image) );
+    if ( !isDiffusionImage )
+        return;
 
-        mitk::DiffusionPropertyHelper propertyHelper(newDwi);
-        propertyHelper.AverageRedundantGradients(m_Controls->m_Blur->value());
-        propertyHelper.InitializeImage();
+    mitk::Image::Pointer newDwi = image->Clone();
+    newDwi->SetPropertyList(image->GetPropertyList()->Clone());
 
-        mitk::DataNode::Pointer imageNode = mitk::DataNode::New();
-        imageNode->SetData( newDwi );
-        QString name = (*itemiter)->GetName().c_str();
-        imageNode->SetName((name+"_averaged").toStdString().c_str());
-        GetDefaultDataStorage()->Add(imageNode, (*itemiter));
+    mitk::DiffusionPropertyHelper propertyHelper(newDwi);
+    propertyHelper.AverageRedundantGradients(m_Controls->m_Blur->value());
+    propertyHelper.InitializeImage();
 
-        ++itemiter;
-    }
+    mitk::DataNode::Pointer imageNode = mitk::DataNode::New();
+    imageNode->SetData( newDwi );
+    QString name = node->GetName().c_str();
+    imageNode->SetName((name+"_averaged").toStdString().c_str());
+    GetDefaultDataStorage()->Add(imageNode, node);
 }
diff --git a/Plugins/org.mitk.gui.qt.diffusionimaging/src/internal/QmitkPreprocessingView.h b/Plugins/org.mitk.gui.qt.diffusionimaging/src/internal/QmitkPreprocessingView.h
index d2e798d963..8b7ccd6cde 100644
--- a/Plugins/org.mitk.gui.qt.diffusionimaging/src/internal/QmitkPreprocessingView.h
+++ b/Plugins/org.mitk.gui.qt.diffusionimaging/src/internal/QmitkPreprocessingView.h
@@ -1,159 +1,159 @@
 /*===================================================================
 
 The Medical Imaging Interaction Toolkit (MITK)
 
 Copyright (c) German Cancer Research Center,
 Division of Medical and Biological Informatics.
 All rights reserved.
 
 This software is distributed WITHOUT ANY WARRANTY; without
 even the implied warranty of MERCHANTABILITY or FITNESS FOR
 A PARTICULAR PURPOSE.
 
 See LICENSE.txt or http://www.mitk.org for details.
 
 ===================================================================*/
 
 #ifndef _QMITKPREPROCESSINGVIEW_H_INCLUDED
 #define _QMITKPREPROCESSINGVIEW_H_INCLUDED
 
 #include <QmitkFunctionality.h>
 
 #include "ui_QmitkPreprocessingViewControls.h"
 
 // st includes
 #include <string>
 
 // itk includes
 #include <itkImage.h>
 #include <itkVectorImage.h>
 
 // mitk includes
 #include <mitkImage.h>
 #include "itkDWIVoxelFunctor.h"
 #include <mitkDiffusionPropertyHelper.h>
 
 typedef short DiffusionPixelType;
 
 struct PrpSelListener;
 
 /*!
  * \ingroup org_mitk_gui_qt_preprocessing_internal
  *
  * \brief QmitkPreprocessingView
  *
  * Document your class here.
  *
  * \sa QmitkFunctionality
  */
 class QmitkPreprocessingView : public QmitkFunctionality
 {
 
   friend struct PrpSelListener;
 
   // this is needed for all Qt objects that should have a MOC object (everything that derives from QObject)
   Q_OBJECT
 
   public:
 
   static const std::string VIEW_ID;
 
   typedef mitk::DiffusionPropertyHelper::GradientDirectionType            GradientDirectionType;
   typedef mitk::DiffusionPropertyHelper::GradientDirectionsContainerType  GradientDirectionContainerType;
   typedef itk::VectorImage< short, 3 >                                    ItkDwiType;
   typedef itk::Image< unsigned char, 3 >                                  UcharImageType;
   typedef itk::Image< double, 3 >                                         ItkDoubleImageType;
 
   QmitkPreprocessingView();
   virtual ~QmitkPreprocessingView();
 
   virtual void CreateQtPartControl(QWidget *parent);
 
   /// \brief Creation of the connections of main and control widget
   virtual void CreateConnections();
 
   /// \brief Called when the functionality is activated
   virtual void Activated();
 
   virtual void Deactivated();
 
   virtual void StdMultiWidgetAvailable (QmitkStdMultiWidget &stdMultiWidget);
   virtual void StdMultiWidgetNotAvailable();
 
   static const int nrconvkernels;
 
 protected slots:
 
   void AverageGradients();
   void ExtractB0();
   void MergeDwis();
   void DoApplySpacing();
   void DoApplyOrigin();
   void DoApplyDirectionMatrix();
   void DoApplyMesurementFrame();
   void DoReduceGradientDirections();
   void DoShowGradientDirections();
   void DoHalfSphereGradientDirections();
   void UpdateDwiBValueMapRounder(int i);
   void DoLengthCorrection();
   void DoAdcCalculation();
   void DoDwiNormalization();
   void DoProjectSignal();
   void DoExtractBrainMask();
   void DoResampleImage();
   void DoCropImage();
   void DoUpdateInterpolationGui(int i);
   void DoRemoveGradient();
   void DoExtractGradient();
+  void DoFlipAxis();
+  void OnImageSelectionChanged();
 
 protected:
 
   void DoADCFit();
   void DoAKCFit();
   void DoBiExpFit();
   void DoADCAverage();
 
+  template < typename TPixel, unsigned int VImageDimension >
+  void TemplatedFlipAxis( itk::Image<TPixel, VImageDimension>* itkImage);
+
   template < typename TPixel, unsigned int VImageDimension >
   void TemplatedCropImage( itk::Image<TPixel, VImageDimension>* itkImage);
 
   template < typename TPixel, unsigned int VImageDimension >
   void TemplatedApplyRotation( itk::Image<TPixel, VImageDimension>* itkImage);
 
   template < typename TPixel, unsigned int VImageDimension >
   void TemplatedUpdateGui( itk::Image<TPixel, VImageDimension>* itkImage);
 
   template < typename TPixel, unsigned int VImageDimension >
   void TemplatedResampleImage( itk::Image<TPixel, VImageDimension>* itkImage);
 
   template < typename TPixel, unsigned int VImageDimension >
   void TemplatedSetImageSpacing( itk::Image<TPixel, VImageDimension>* itkImage);
 
   template < typename TPixel, unsigned int VImageDimension >
   void TemplatedSetImageOrigin( itk::Image<TPixel, VImageDimension>* itkImage);
 
   /** Called by ExtractB0 if check-box activated, extracts all b0 images without averaging */
   void DoExtractBOWithoutAveraging();
 
   void UpdateBValueTableWidget(int i);
 
   /// \brief called by QmitkFunctionality when DataManager's selection has changed
-  virtual void OnSelectionChanged( std::vector<mitk::DataNode*> nodes );
+//  virtual void OnSelectionChanged( std::vector<mitk::DataNode*> nodes );
 
   Ui::QmitkPreprocessingViewControls* m_Controls;
 
   QmitkStdMultiWidget* m_MultiWidget;
 
   void SetDefaultNodeProperties(mitk::DataNode::Pointer node, std::string name);
-
-  mitk::DataNode::Pointer                           m_SelectedImageNode;
-  mitk::Image::Pointer                              m_SelectedImage;
-  std::vector< mitk::DataNode::Pointer >            m_SelectedDiffusionNodes;
-
   void CallMultishellToSingleShellFilter(itk::DWIVoxelFunctor * functor, mitk::Image::Pointer ImPtr, QString imageName, mitk::DataNode* parent);
 };
 
 
 
 
 #endif // _QMITKPREPROCESSINGVIEW_H_INCLUDED
 
diff --git a/Plugins/org.mitk.gui.qt.diffusionimaging/src/internal/QmitkPreprocessingViewControls.ui b/Plugins/org.mitk.gui.qt.diffusionimaging/src/internal/QmitkPreprocessingViewControls.ui
index b2460f04b2..1641e5acfa 100644
--- a/Plugins/org.mitk.gui.qt.diffusionimaging/src/internal/QmitkPreprocessingViewControls.ui
+++ b/Plugins/org.mitk.gui.qt.diffusionimaging/src/internal/QmitkPreprocessingViewControls.ui
@@ -1,1574 +1,1645 @@
 <?xml version="1.0" encoding="UTF-8"?>
 <ui version="4.0">
  <class>QmitkPreprocessingViewControls</class>
  <widget class="QWidget" name="QmitkPreprocessingViewControls">
   <property name="geometry">
    <rect>
     <x>0</x>
     <y>0</y>
-    <width>639</width>
-    <height>1148</height>
+    <width>523</width>
+    <height>1158</height>
    </rect>
   </property>
   <property name="minimumSize">
    <size>
     <width>0</width>
     <height>0</height>
    </size>
   </property>
   <property name="acceptDrops">
    <bool>false</bool>
   </property>
   <property name="windowTitle">
    <string>QmitkPreprocessingViewControls</string>
   </property>
   <property name="autoFillBackground">
    <bool>true</bool>
   </property>
   <layout class="QVBoxLayout" name="verticalLayout">
    <item>
     <widget class="QGroupBox" name="m_InputData">
      <property name="title">
       <string>Please Select Input Data</string>
      </property>
      <layout class="QGridLayout" name="gridLayout_2">
       <item row="0" column="0">
        <widget class="QLabel" name="label_5">
         <property name="toolTip">
          <string/>
         </property>
         <property name="text">
          <string>Image:</string>
         </property>
        </widget>
       </item>
       <item row="0" column="1">
-       <widget class="QLabel" name="m_DiffusionImageLabel">
-        <property name="text">
-         <string>&lt;html&gt;&lt;head/&gt;&lt;body&gt;&lt;p&gt;&lt;span style=&quot; color:#ff0000;&quot;&gt;mandatory&lt;/span&gt;&lt;/p&gt;&lt;/body&gt;&lt;/html&gt;</string>
-        </property>
-        <property name="wordWrap">
-         <bool>true</bool>
+       <widget class="QmitkDataStorageComboBox" name="m_SelctedImageComboBox">
+        <property name="sizeAdjustPolicy">
+         <enum>QComboBox::AdjustToMinimumContentsLength</enum>
         </property>
        </widget>
       </item>
      </layout>
     </widget>
    </item>
    <item>
     <widget class="QTabWidget" name="tabWidget">
      <property name="currentIndex">
       <number>0</number>
      </property>
      <widget class="QWidget" name="tab_4">
       <attribute name="title">
        <string>Gradients</string>
       </attribute>
       <layout class="QGridLayout" name="gridLayout_6">
-       <item row="5" column="0">
-        <spacer name="verticalSpacer_5">
-         <property name="orientation">
-          <enum>Qt::Vertical</enum>
+       <item row="0" column="0">
+        <widget class="QTableWidget" name="m_B_ValueMap_TableWidget">
+         <property name="sizePolicy">
+          <sizepolicy hsizetype="Minimum" vsizetype="Minimum">
+           <horstretch>0</horstretch>
+           <verstretch>0</verstretch>
+          </sizepolicy>
          </property>
-         <property name="sizeHint" stdset="0">
-          <size>
-           <width>20</width>
-           <height>40</height>
-          </size>
+         <property name="verticalScrollBarPolicy">
+          <enum>Qt::ScrollBarAsNeeded</enum>
          </property>
-        </spacer>
+         <property name="horizontalScrollBarPolicy">
+          <enum>Qt::ScrollBarAlwaysOff</enum>
+         </property>
+         <attribute name="horizontalHeaderCascadingSectionResizes">
+          <bool>true</bool>
+         </attribute>
+         <attribute name="horizontalHeaderDefaultSectionSize">
+          <number>100</number>
+         </attribute>
+         <attribute name="horizontalHeaderStretchLastSection">
+          <bool>true</bool>
+         </attribute>
+         <attribute name="verticalHeaderVisible">
+          <bool>false</bool>
+         </attribute>
+         <attribute name="verticalHeaderCascadingSectionResizes">
+          <bool>true</bool>
+         </attribute>
+         <column>
+          <property name="text">
+           <string>b-Value</string>
+          </property>
+         </column>
+         <column>
+          <property name="text">
+           <string>Number of gradients</string>
+          </property>
+         </column>
+        </widget>
        </item>
        <item row="3" column="0">
         <widget class="QFrame" name="frame_2">
          <property name="frameShape">
           <enum>QFrame::NoFrame</enum>
          </property>
          <property name="frameShadow">
           <enum>QFrame::Raised</enum>
          </property>
          <layout class="QGridLayout" name="gridLayout_10">
           <property name="leftMargin">
            <number>0</number>
           </property>
           <property name="topMargin">
            <number>0</number>
           </property>
           <property name="rightMargin">
            <number>0</number>
           </property>
           <property name="bottomMargin">
            <number>0</number>
           </property>
           <property name="horizontalSpacing">
            <number>6</number>
           </property>
           <item row="5" column="0">
            <widget class="QCommandLinkButton" name="m_MirrorGradientToHalfSphereButton">
             <property name="enabled">
              <bool>false</bool>
             </property>
             <property name="toolTip">
              <string>Sometimes the gradient directions are not located on one half sphere.</string>
             </property>
             <property name="statusTip">
              <string/>
             </property>
             <property name="whatsThis">
              <string notr="true"/>
             </property>
             <property name="text">
              <string>Mirror gradients to half sphere</string>
             </property>
            </widget>
           </item>
           <item row="3" column="0">
            <widget class="QCommandLinkButton" name="m_CreateLengthCorrectedDwi">
             <property name="enabled">
              <bool>false</bool>
             </property>
             <property name="text">
              <string>Round b-values</string>
             </property>
            </widget>
           </item>
           <item row="7" column="0">
            <widget class="QCommandLinkButton" name="m_ReduceGradientsButton">
             <property name="enabled">
              <bool>false</bool>
             </property>
             <property name="toolTip">
              <string>Retain only the specified number of gradient directions and according image volumes. The retained directions are spread equally over the half sphere using an iterative energy repulsion strategy.</string>
             </property>
             <property name="statusTip">
              <string/>
             </property>
             <property name="whatsThis">
              <string notr="true"/>
             </property>
             <property name="text">
              <string>Reduce number of gradients</string>
             </property>
            </widget>
           </item>
           <item row="3" column="1">
            <layout class="QFormLayout" name="formLayout">
             <item row="0" column="0">
              <widget class="QLabel" name="label_2">
               <property name="toolTip">
                <string>&lt;html&gt;&lt;head/&gt;&lt;body&gt;&lt;p&gt;Define the sampling frame the b-Values are rounded with.&lt;/p&gt;&lt;/body&gt;&lt;/html&gt;</string>
               </property>
               <property name="text">
                <string>Sampling frame:</string>
               </property>
              </widget>
             </item>
             <item row="0" column="1">
              <widget class="QSpinBox" name="m_B_ValueMap_Rounder_SpinBox">
               <property name="enabled">
                <bool>false</bool>
               </property>
               <property name="toolTip">
                <string>&lt;html&gt;&lt;head/&gt;&lt;body&gt;&lt;p&gt;Round b-values to nearest multiple of this value (click &amp;quot;Round b-value&amp;quot; to create new image with these values).&lt;/p&gt;&lt;/body&gt;&lt;/html&gt;</string>
               </property>
               <property name="correctionMode">
                <enum>QAbstractSpinBox::CorrectToNearestValue</enum>
               </property>
               <property name="minimum">
                <number>1</number>
               </property>
               <property name="maximum">
                <number>10000</number>
               </property>
               <property name="singleStep">
                <number>10</number>
               </property>
              </widget>
             </item>
            </layout>
           </item>
           <item row="4" column="0">
            <widget class="QCommandLinkButton" name="m_ShowGradientsButton">
             <property name="enabled">
              <bool>false</bool>
             </property>
             <property name="toolTip">
              <string>Generate pointset displaying the gradient vectors (applied measurement frame).</string>
             </property>
             <property name="statusTip">
              <string/>
             </property>
             <property name="whatsThis">
              <string notr="true"/>
             </property>
             <property name="text">
              <string>Show gradients</string>
             </property>
            </widget>
           </item>
          </layout>
         </widget>
        </item>
-       <item row="0" column="0">
-        <widget class="QTableWidget" name="m_B_ValueMap_TableWidget">
-         <property name="sizePolicy">
-          <sizepolicy hsizetype="Minimum" vsizetype="Minimum">
-           <horstretch>0</horstretch>
-           <verstretch>0</verstretch>
-          </sizepolicy>
-         </property>
-         <property name="verticalScrollBarPolicy">
-          <enum>Qt::ScrollBarAsNeeded</enum>
-         </property>
-         <property name="horizontalScrollBarPolicy">
-          <enum>Qt::ScrollBarAlwaysOff</enum>
-         </property>
-         <attribute name="horizontalHeaderCascadingSectionResizes">
-          <bool>true</bool>
-         </attribute>
-         <attribute name="horizontalHeaderDefaultSectionSize">
-          <number>100</number>
-         </attribute>
-         <attribute name="horizontalHeaderStretchLastSection">
-          <bool>true</bool>
-         </attribute>
-         <attribute name="verticalHeaderVisible">
-          <bool>false</bool>
-         </attribute>
-         <attribute name="verticalHeaderCascadingSectionResizes">
-          <bool>true</bool>
-         </attribute>
-         <column>
-          <property name="text">
-           <string>b-Value</string>
-          </property>
-         </column>
-         <column>
-          <property name="text">
-           <string>Number of gradients</string>
-          </property>
-         </column>
-        </widget>
-       </item>
-       <item row="0" column="1">
-        <spacer name="horizontalSpacer_5">
+       <item row="5" column="0">
+        <spacer name="verticalSpacer_5">
          <property name="orientation">
-          <enum>Qt::Horizontal</enum>
+          <enum>Qt::Vertical</enum>
          </property>
          <property name="sizeHint" stdset="0">
           <size>
-           <width>40</width>
-           <height>20</height>
+           <width>20</width>
+           <height>40</height>
           </size>
          </property>
         </spacer>
        </item>
       </layout>
      </widget>
      <widget class="QWidget" name="tab_5">
       <attribute name="title">
        <string>Image Values</string>
       </attribute>
       <layout class="QGridLayout" name="gridLayout_8">
        <item row="3" column="0">
         <spacer name="verticalSpacer">
          <property name="orientation">
           <enum>Qt::Vertical</enum>
          </property>
          <property name="sizeHint" stdset="0">
           <size>
            <width>20</width>
            <height>40</height>
           </size>
          </property>
         </spacer>
        </item>
        <item row="0" column="0">
         <widget class="QFrame" name="frame_3">
          <property name="frameShape">
           <enum>QFrame::NoFrame</enum>
          </property>
          <property name="frameShadow">
           <enum>QFrame::Raised</enum>
          </property>
          <layout class="QGridLayout" name="gridLayout_11">
           <property name="leftMargin">
            <number>0</number>
           </property>
           <property name="topMargin">
            <number>0</number>
           </property>
           <property name="rightMargin">
            <number>0</number>
           </property>
           <property name="bottomMargin">
            <number>0</number>
           </property>
           <property name="horizontalSpacing">
            <number>0</number>
           </property>
           <item row="1" column="1">
            <widget class="QFrame" name="frame">
             <property name="frameShape">
              <enum>QFrame::NoFrame</enum>
             </property>
             <property name="frameShadow">
              <enum>QFrame::Raised</enum>
             </property>
             <layout class="QFormLayout" name="formLayout_2">
              <property name="leftMargin">
               <number>0</number>
              </property>
              <property name="topMargin">
               <number>0</number>
              </property>
              <property name="rightMargin">
               <number>0</number>
              </property>
              <property name="bottomMargin">
               <number>0</number>
              </property>
              <item row="0" column="1">
               <widget class="QDoubleSpinBox" name="m_Blur">
                <property name="toolTip">
                 <string comment="Accumulates the information that was acquired with multiple repetitions for one gradient. Vectors do not have to be precisely equal in order to be merged, if a &quot;Merge radius&quot; &gt; 0 is configured." extracomment="Accumulates the information that was acquired with multiple repetitions for one gradient. Vectors do not have to be precisely equal in order to be merged, if a &quot;Merge radius&quot; &gt; 0 is configured.">Accumulates the information that was acquired with multiple repetitions for one gradient. Vectors do not have to be precisely equal in order to be merged, if a &quot;Merge radius&quot; &gt; 0 is configured.</string>
                </property>
                <property name="statusTip">
                 <string comment="Accumulates the information that was acquired with multiple repetitions for one gradient. Vectors do not have to be precisely equal in order to be merged, if a &quot;Merge radius&quot; &gt; 0 is configured." extracomment="Accumulates the information that was acquired with multiple repetitions for one gradient. Vectors do not have to be precisely equal in order to be merged, if a &quot;Merge radius&quot; &gt; 0 is configured.">Accumulates the information that was acquired with multiple repetitions for one gradient. Vectors do not have to be precisely equal in order to be merged, if a &quot;Merge radius&quot; &gt; 0 is configured.</string>
                </property>
                <property name="whatsThis">
                 <string comment="Accumulates the information that was acquired with multiple repetitions for one gradient. Vectors do not have to be precisely equal in order to be merged, if a &quot;Merge radius&quot; &gt; 0 is configured." extracomment="Accumulates the information that was acquired with multiple repetitions for one gradient. Vectors do not have to be precisely equal in order to be merged, if a &quot;Merge radius&quot; &gt; 0 is configured.">Accumulates the information that was acquired with multiple repetitions for one gradient. Vectors do not have to be precisely equal in order to be merged, if a &quot;Merge radius&quot; &gt; 0 is configured.</string>
                </property>
                <property name="decimals">
                 <number>6</number>
                </property>
                <property name="maximum">
                 <double>2.000000000000000</double>
                </property>
                <property name="singleStep">
                 <double>0.000100000000000</double>
                </property>
                <property name="value">
                 <double>0.001000000000000</double>
                </property>
               </widget>
              </item>
              <item row="0" column="0">
               <widget class="QLabel" name="label">
                <property name="toolTip">
                 <string comment="Accumulates the information that was acquired with multiple repetitions for one gradient. Vectors do not have to be precisely equal in order to be merged, if a &quot;Merge radius&quot; &gt; 0 is configured." extracomment="Accumulates the information that was acquired with multiple repetitions for one gradient. Vectors do not have to be precisely equal in order to be merged, if a &quot;Merge radius&quot; &gt; 0 is configured.">Accumulates the information that was acquired with multiple repetitions for one gradient. Vectors do not have to be precisely equal in order to be merged, if a &quot;Merge radius&quot; &gt; 0 is configured.</string>
                </property>
                <property name="statusTip">
                 <string comment="Accumulates the information that was acquired with multiple repetitions for one gradient. Vectors do not have to be precisely equal in order to be merged, if a &quot;Merge radius&quot; &gt; 0 is configured." extracomment="Accumulates the information that was acquired with multiple repetitions for one gradient. Vectors do not have to be precisely equal in order to be merged, if a &quot;Merge radius&quot; &gt; 0 is configured.">Accumulates the information that was acquired with multiple repetitions for one gradient. Vectors do not have to be precisely equal in order to be merged, if a &quot;Merge radius&quot; &gt; 0 is configured.</string>
                </property>
                <property name="whatsThis">
                 <string comment="Accumulates the information that was acquired with multiple repetitions for one gradient. Vectors do not have to be precisely equal in order to be merged, if a &quot;Merge radius&quot; &gt; 0 is configured." extracomment="Accumulates the information that was acquired with multiple repetitions for one gradient. Vectors do not have to be precisely equal in order to be merged, if a &quot;Merge radius&quot; &gt; 0 is configured.">Accumulates the information that was acquired with multiple repetitions for one gradient. Vectors do not have to be precisely equal in order to be merged, if a &quot;Merge radius&quot; &gt; 0 is configured.</string>
                </property>
                <property name="text">
                 <string>Merge radius</string>
                </property>
               </widget>
              </item>
             </layout>
            </widget>
           </item>
           <item row="6" column="0">
            <widget class="QCommandLinkButton" name="m_MergeDwisButton">
             <property name="enabled">
              <bool>false</bool>
             </property>
             <property name="toolTip">
              <string>Merges selected DWIs of same dimension. If several b-values are present, the resulting image will contain multiple b-shells.</string>
             </property>
             <property name="statusTip">
              <string/>
             </property>
             <property name="whatsThis">
              <string notr="true"/>
             </property>
             <property name="text">
              <string>Merge selected DWIs</string>
             </property>
            </widget>
           </item>
           <item row="3" column="0">
            <widget class="QCommandLinkButton" name="m_NormalizeImageValuesButton">
             <property name="enabled">
              <bool>false</bool>
             </property>
             <property name="toolTip">
              <string/>
             </property>
             <property name="statusTip">
              <string/>
             </property>
             <property name="whatsThis">
              <string notr="true"/>
             </property>
             <property name="text">
              <string>Normalize image values</string>
             </property>
            </widget>
           </item>
           <item row="2" column="1">
            <widget class="QFrame" name="frame_4">
             <property name="frameShape">
              <enum>QFrame::NoFrame</enum>
             </property>
             <property name="frameShadow">
              <enum>QFrame::Raised</enum>
             </property>
             <layout class="QGridLayout" name="gridLayout_4">
              <property name="leftMargin">
               <number>0</number>
              </property>
              <property name="topMargin">
               <number>0</number>
              </property>
              <property name="rightMargin">
               <number>0</number>
              </property>
              <property name="bottomMargin">
               <number>0</number>
              </property>
              <property name="spacing">
               <number>0</number>
              </property>
              <item row="0" column="0">
               <widget class="QSpinBox" name="m_targetBValueSpinBox">
                <property name="enabled">
                 <bool>false</bool>
                </property>
                <property name="toolTip">
                 <string>Target b-value</string>
                </property>
                <property name="maximum">
                 <number>100000</number>
                </property>
                <property name="singleStep">
                 <number>500</number>
                </property>
               </widget>
              </item>
              <item row="0" column="1">
               <widget class="QComboBox" name="m_ProjectionMethodBox">
                <property name="toolTip">
                 <string>Select projection method.</string>
                </property>
+               <property name="sizeAdjustPolicy">
+                <enum>QComboBox::AdjustToMinimumContentsLength</enum>
+               </property>
                <item>
                 <property name="text">
                  <string>ADC Average</string>
                 </property>
                </item>
                <item>
                 <property name="text">
                  <string>AKC</string>
                 </property>
                </item>
                <item>
                 <property name="text">
                  <string>Bi-Exponential</string>
                 </property>
                </item>
               </widget>
              </item>
             </layout>
            </widget>
           </item>
           <item row="1" column="0">
            <widget class="QCommandLinkButton" name="m_ButtonAverageGradients">
             <property name="enabled">
              <bool>false</bool>
             </property>
             <property name="toolTip">
              <string>Multiple acquistions of one gradient direction can be averaged. Due to rounding errors, similar gradients often differ in the last decimal positions. The Merge radius allows to average them by taking all directions within a certain radius into account.</string>
             </property>
             <property name="statusTip">
              <string/>
             </property>
             <property name="whatsThis">
              <string notr="true"/>
             </property>
             <property name="text">
              <string>Average repetitions</string>
             </property>
            </widget>
           </item>
           <item row="2" column="0">
            <widget class="QCommandLinkButton" name="m_ProjectSignalButton">
             <property name="enabled">
              <bool>false</bool>
             </property>
             <property name="toolTip">
              <string>Project image values onto one b-shell.</string>
             </property>
             <property name="text">
              <string>Project onto shell</string>
             </property>
            </widget>
           </item>
           <item row="3" column="1">
            <widget class="QFrame" name="frame_6">
             <property name="frameShape">
              <enum>QFrame::NoFrame</enum>
             </property>
             <property name="frameShadow">
              <enum>QFrame::Raised</enum>
             </property>
             <layout class="QGridLayout" name="gridLayout_19">
              <property name="leftMargin">
               <number>0</number>
              </property>
              <property name="topMargin">
               <number>0</number>
              </property>
              <property name="rightMargin">
               <number>0</number>
              </property>
              <property name="bottomMargin">
               <number>0</number>
              </property>
              <property name="verticalSpacing">
               <number>0</number>
              </property>
              <item row="0" column="1">
               <widget class="QmitkDataStorageComboBox" name="m_NormalizationMaskBox">
                <property name="toolTip">
                 <string>Select binary mask image.</string>
                </property>
+               <property name="sizeAdjustPolicy">
+                <enum>QComboBox::AdjustToMinimumContentsLength</enum>
+               </property>
               </widget>
              </item>
              <item row="0" column="0">
               <widget class="QmitkDataStorageComboBox" name="m_NormalizationReferenceBox">
                <property name="toolTip">
                 <string>Select normalization reference.</string>
                </property>
+               <property name="sizeAdjustPolicy">
+                <enum>QComboBox::AdjustToMinimumContentsLength</enum>
+               </property>
                <item>
                 <property name="text">
                  <string>White matter</string>
                 </property>
                </item>
                <item>
                 <property name="text">
                  <string>CSF</string>
                 </property>
                </item>
                <item>
                 <property name="text">
                  <string>Voxel-wise baseline</string>
                 </property>
                </item>
               </widget>
              </item>
             </layout>
            </widget>
           </item>
+          <item row="4" column="0">
+           <widget class="QCommandLinkButton" name="m_FlipAxis">
+            <property name="enabled">
+             <bool>false</bool>
+            </property>
+            <property name="toolTip">
+             <string>Merges selected DWIs of same dimension. If several b-values are present, the resulting image will contain multiple b-shells.</string>
+            </property>
+            <property name="statusTip">
+             <string/>
+            </property>
+            <property name="whatsThis">
+             <string notr="true"/>
+            </property>
+            <property name="text">
+             <string>Flip axis</string>
+            </property>
+           </widget>
+          </item>
+          <item row="4" column="1">
+           <widget class="QFrame" name="frame_7">
+            <property name="frameShape">
+             <enum>QFrame::NoFrame</enum>
+            </property>
+            <property name="frameShadow">
+             <enum>QFrame::Raised</enum>
+            </property>
+            <layout class="QGridLayout" name="gridLayout_20">
+             <property name="leftMargin">
+              <number>0</number>
+             </property>
+             <property name="topMargin">
+              <number>0</number>
+             </property>
+             <property name="rightMargin">
+              <number>0</number>
+             </property>
+             <property name="bottomMargin">
+              <number>0</number>
+             </property>
+             <item row="0" column="2">
+              <widget class="QCheckBox" name="m_FlipY">
+               <property name="text">
+                <string>Y</string>
+               </property>
+              </widget>
+             </item>
+             <item row="0" column="4">
+              <spacer name="horizontalSpacer_4">
+               <property name="orientation">
+                <enum>Qt::Horizontal</enum>
+               </property>
+               <property name="sizeHint" stdset="0">
+                <size>
+                 <width>40</width>
+                 <height>20</height>
+                </size>
+               </property>
+              </spacer>
+             </item>
+             <item row="0" column="1">
+              <widget class="QCheckBox" name="m_FlipX">
+               <property name="text">
+                <string>X</string>
+               </property>
+              </widget>
+             </item>
+             <item row="0" column="3">
+              <widget class="QCheckBox" name="m_FlipZ">
+               <property name="text">
+                <string>Z</string>
+               </property>
+              </widget>
+             </item>
+             <item row="0" column="0">
+              <widget class="QLabel" name="label_8">
+               <property name="text">
+                <string>Axis:</string>
+               </property>
+              </widget>
+             </item>
+            </layout>
+           </widget>
+          </item>
+          <item row="6" column="1">
+           <widget class="QmitkDataStorageComboBox" name="m_MergeDwiBox">
+            <property name="sizeAdjustPolicy">
+             <enum>QComboBox::AdjustToMinimumContentsLength</enum>
+            </property>
+           </widget>
+          </item>
          </layout>
         </widget>
        </item>
        <item row="1" column="0">
         <widget class="QGroupBox" name="groupBox_2">
          <property name="title">
           <string>Resample image</string>
          </property>
          <layout class="QGridLayout" name="gridLayout_12">
           <item row="1" column="0">
            <widget class="QFrame" name="m_ResampleDoubleFrame">
             <property name="frameShape">
              <enum>QFrame::NoFrame</enum>
             </property>
             <property name="frameShadow">
              <enum>QFrame::Raised</enum>
             </property>
             <layout class="QGridLayout" name="gridLayout_5">
              <property name="leftMargin">
               <number>0</number>
              </property>
              <property name="topMargin">
               <number>0</number>
              </property>
              <property name="rightMargin">
               <number>0</number>
              </property>
              <property name="bottomMargin">
               <number>0</number>
              </property>
              <property name="spacing">
               <number>0</number>
              </property>
              <item row="0" column="1">
               <widget class="QDoubleSpinBox" name="m_ResampleDoubleY">
                <property name="minimum">
                 <double>0.010000000000000</double>
                </property>
                <property name="value">
                 <double>2.000000000000000</double>
                </property>
               </widget>
              </item>
              <item row="0" column="0">
               <widget class="QDoubleSpinBox" name="m_ResampleDoubleX">
                <property name="minimum">
                 <double>0.010000000000000</double>
                </property>
                <property name="value">
                 <double>2.000000000000000</double>
                </property>
               </widget>
              </item>
              <item row="0" column="2">
               <widget class="QDoubleSpinBox" name="m_ResampleDoubleZ">
                <property name="minimum">
                 <double>0.010000000000000</double>
                </property>
                <property name="value">
                 <double>2.000000000000000</double>
                </property>
               </widget>
              </item>
             </layout>
            </widget>
           </item>
           <item row="0" column="0">
            <widget class="QComboBox" name="m_ResampleTypeBox">
             <item>
              <property name="text">
               <string>Sampling factor</string>
              </property>
             </item>
             <item>
              <property name="text">
               <string>New image spacing</string>
              </property>
             </item>
             <item>
              <property name="text">
               <string>New image size</string>
              </property>
             </item>
            </widget>
           </item>
           <item row="3" column="0">
            <widget class="QFrame" name="frame_5">
             <property name="frameShape">
              <enum>QFrame::NoFrame</enum>
             </property>
             <property name="frameShadow">
              <enum>QFrame::Raised</enum>
             </property>
             <layout class="QGridLayout" name="gridLayout_14">
              <property name="leftMargin">
               <number>0</number>
              </property>
              <property name="topMargin">
               <number>0</number>
              </property>
              <property name="rightMargin">
               <number>0</number>
              </property>
              <property name="bottomMargin">
               <number>0</number>
              </property>
              <property name="spacing">
               <number>0</number>
              </property>
              <item row="0" column="0">
               <widget class="QLabel" name="label_3">
                <property name="text">
                 <string>Interpolator:</string>
                </property>
               </widget>
              </item>
              <item row="0" column="1">
               <widget class="QComboBox" name="m_InterpolatorBox">
                <item>
                 <property name="text">
                  <string>Nearest neighbour</string>
                 </property>
                </item>
                <item>
                 <property name="text">
                  <string>Linear</string>
                 </property>
                </item>
                <item>
                 <property name="text">
                  <string>B-spline</string>
                 </property>
                </item>
                <item>
                 <property name="text">
                  <string>Windowed sinc</string>
                 </property>
                </item>
               </widget>
              </item>
              <item row="1" column="0">
               <widget class="QCommandLinkButton" name="m_ResampleImageButton">
                <property name="enabled">
                 <bool>false</bool>
                </property>
                <property name="toolTip">
                 <string/>
                </property>
                <property name="statusTip">
                 <string/>
                </property>
                <property name="whatsThis">
                 <string notr="true"/>
                </property>
                <property name="text">
                 <string>Resample image</string>
                </property>
               </widget>
              </item>
             </layout>
            </widget>
           </item>
           <item row="2" column="0">
            <widget class="QFrame" name="m_ResampleIntFrame">
             <property name="frameShape">
              <enum>QFrame::NoFrame</enum>
             </property>
             <property name="frameShadow">
              <enum>QFrame::Raised</enum>
             </property>
             <layout class="QGridLayout" name="gridLayout_13">
              <property name="leftMargin">
               <number>0</number>
              </property>
              <property name="topMargin">
               <number>0</number>
              </property>
              <property name="rightMargin">
               <number>0</number>
              </property>
              <property name="bottomMargin">
               <number>0</number>
              </property>
              <property name="spacing">
               <number>0</number>
              </property>
              <item row="0" column="0">
               <widget class="QSpinBox" name="m_ResampleIntX">
                <property name="minimum">
                 <number>1</number>
                </property>
                <property name="maximum">
                 <number>10000</number>
                </property>
               </widget>
              </item>
              <item row="0" column="1">
               <widget class="QSpinBox" name="m_ResampleIntY">
                <property name="minimum">
                 <number>1</number>
                </property>
                <property name="maximum">
                 <number>10000</number>
                </property>
               </widget>
              </item>
              <item row="0" column="2">
               <widget class="QSpinBox" name="m_ResampleIntZ">
                <property name="minimum">
                 <number>1</number>
                </property>
                <property name="maximum">
                 <number>10000</number>
                </property>
               </widget>
              </item>
             </layout>
            </widget>
           </item>
          </layout>
         </widget>
        </item>
       </layout>
      </widget>
      <widget class="QWidget" name="tab_3">
       <attribute name="title">
        <string>Header</string>
       </attribute>
       <layout class="QGridLayout" name="gridLayout_7">
-       <item row="7" column="0">
-        <spacer name="verticalSpacer_2">
-         <property name="orientation">
-          <enum>Qt::Vertical</enum>
-         </property>
-         <property name="sizeHint" stdset="0">
-          <size>
-           <width>20</width>
-           <height>40</height>
-          </size>
-         </property>
-        </spacer>
-       </item>
-       <item row="2" column="0">
-        <widget class="QGroupBox" name="groupBox_3">
-         <property name="title">
-          <string>Voxel size</string>
-         </property>
-         <layout class="QGridLayout" name="gridLayout_16">
-          <property name="leftMargin">
-           <number>0</number>
-          </property>
-          <property name="rightMargin">
-           <number>0</number>
-          </property>
-          <property name="bottomMargin">
-           <number>0</number>
-          </property>
-          <item row="0" column="0">
-           <widget class="QDoubleSpinBox" name="m_HeaderSpacingX">
-            <property name="decimals">
-             <number>4</number>
-            </property>
-           </widget>
-          </item>
-          <item row="0" column="1">
-           <widget class="QDoubleSpinBox" name="m_HeaderSpacingY">
-            <property name="decimals">
-             <number>4</number>
-            </property>
-           </widget>
-          </item>
-          <item row="0" column="2">
-           <widget class="QDoubleSpinBox" name="m_HeaderSpacingZ">
-            <property name="decimals">
-             <number>4</number>
-            </property>
-            <property name="minimum">
-             <double>0.000000000000000</double>
-            </property>
-            <property name="maximum">
-             <double>99.989999999999995</double>
-            </property>
-           </widget>
-          </item>
-          <item row="1" column="0">
-           <widget class="QCommandLinkButton" name="m_ModifySpacingButton">
-            <property name="enabled">
-             <bool>false</bool>
-            </property>
-            <property name="toolTip">
-             <string/>
-            </property>
-            <property name="statusTip">
-             <string/>
-            </property>
-            <property name="whatsThis">
-             <string notr="true"/>
-            </property>
-            <property name="text">
-             <string>Set new voxel size</string>
-            </property>
-           </widget>
-          </item>
-         </layout>
-        </widget>
-       </item>
        <item row="3" column="0">
         <widget class="QGroupBox" name="groupBox_6">
          <property name="title">
           <string>Image size</string>
          </property>
          <layout class="QGridLayout" name="gridLayout_15">
           <property name="leftMargin">
            <number>0</number>
           </property>
           <property name="rightMargin">
            <number>0</number>
           </property>
           <property name="bottomMargin">
            <number>0</number>
           </property>
           <item row="1" column="0">
            <widget class="QLabel" name="label_6">
             <property name="text">
              <string>y:</string>
             </property>
            </widget>
           </item>
           <item row="1" column="1">
            <widget class="QSpinBox" name="m_YstartBox">
             <property name="toolTip">
              <string>Number of pixels to remove on lower image bound.</string>
             </property>
             <property name="maximum">
              <number>999999999</number>
             </property>
            </widget>
           </item>
           <item row="2" column="2">
            <widget class="QSpinBox" name="m_ZendBox">
             <property name="toolTip">
              <string>Number of pixels to remove on upper image bound.</string>
             </property>
             <property name="maximum">
              <number>999999999</number>
             </property>
            </widget>
           </item>
           <item row="0" column="2">
            <widget class="QSpinBox" name="m_XendBox">
             <property name="toolTip">
              <string>Number of pixels to remove on upper image bound.</string>
             </property>
             <property name="maximum">
              <number>999999999</number>
             </property>
            </widget>
           </item>
           <item row="0" column="1">
            <widget class="QSpinBox" name="m_XstartBox">
             <property name="toolTip">
              <string>Number of pixels to remove on lower image bound.</string>
             </property>
             <property name="maximum">
              <number>999999999</number>
             </property>
            </widget>
           </item>
           <item row="0" column="0">
            <widget class="QLabel" name="label_4">
             <property name="text">
              <string>x:</string>
             </property>
            </widget>
           </item>
           <item row="2" column="1">
            <widget class="QSpinBox" name="m_ZstartBox">
             <property name="toolTip">
              <string>Number of pixels to remove on lower image bound.</string>
             </property>
             <property name="maximum">
              <number>999999999</number>
             </property>
            </widget>
           </item>
           <item row="1" column="2">
            <widget class="QSpinBox" name="m_YendBox">
             <property name="toolTip">
              <string>Number of pixels to remove on upper image bound.</string>
             </property>
             <property name="maximum">
              <number>999999999</number>
             </property>
            </widget>
           </item>
           <item row="2" column="0">
            <widget class="QLabel" name="label_7">
             <property name="text">
              <string>z:</string>
             </property>
            </widget>
           </item>
           <item row="3" column="0">
            <widget class="QCommandLinkButton" name="m_CropImageButton">
             <property name="enabled">
              <bool>false</bool>
             </property>
             <property name="toolTip">
              <string/>
             </property>
             <property name="statusTip">
              <string/>
             </property>
             <property name="whatsThis">
              <string notr="true"/>
             </property>
             <property name="text">
              <string>Crop image</string>
             </property>
            </widget>
           </item>
          </layout>
         </widget>
        </item>
-       <item row="1" column="0">
-        <widget class="QGroupBox" name="groupBox_5">
+       <item row="4" column="0">
+        <widget class="QGroupBox" name="groupBox_7">
          <property name="title">
-          <string>Origin</string>
+          <string>Remove or extract gradient volumes</string>
          </property>
-         <layout class="QGridLayout" name="gridLayout_17">
+         <layout class="QGridLayout" name="gridLayout_18">
+          <item row="0" column="0">
+           <widget class="QCommandLinkButton" name="m_RemoveGradientButton">
+            <property name="enabled">
+             <bool>false</bool>
+            </property>
+            <property name="toolTip">
+             <string>Generate pointset displaying the gradient vectors (applied measurement frame).</string>
+            </property>
+            <property name="statusTip">
+             <string/>
+            </property>
+            <property name="whatsThis">
+             <string notr="true"/>
+            </property>
+            <property name="text">
+             <string>Remove</string>
+            </property>
+           </widget>
+          </item>
+          <item row="1" column="0">
+           <widget class="QCommandLinkButton" name="m_ExtractGradientButton">
+            <property name="enabled">
+             <bool>false</bool>
+            </property>
+            <property name="toolTip">
+             <string>Generate pointset displaying the gradient vectors (applied measurement frame).</string>
+            </property>
+            <property name="statusTip">
+             <string/>
+            </property>
+            <property name="whatsThis">
+             <string notr="true"/>
+            </property>
+            <property name="text">
+             <string>Extract</string>
+            </property>
+           </widget>
+          </item>
+          <item row="1" column="1">
+           <widget class="QSpinBox" name="m_ExtractGradientBox"/>
+          </item>
+          <item row="0" column="1">
+           <widget class="QSpinBox" name="m_RemoveGradientBox"/>
+          </item>
+         </layout>
+        </widget>
+       </item>
+       <item row="2" column="0">
+        <widget class="QGroupBox" name="groupBox_3">
+         <property name="title">
+          <string>Voxel size</string>
+         </property>
+         <layout class="QGridLayout" name="gridLayout_16">
           <property name="leftMargin">
            <number>0</number>
           </property>
           <property name="rightMargin">
            <number>0</number>
           </property>
           <property name="bottomMargin">
            <number>0</number>
           </property>
           <item row="0" column="0">
-           <widget class="QDoubleSpinBox" name="m_HeaderOriginX">
+           <widget class="QDoubleSpinBox" name="m_HeaderSpacingX">
             <property name="decimals">
              <number>4</number>
             </property>
-            <property name="minimum">
-             <double>-999999999.000000000000000</double>
-            </property>
-            <property name="maximum">
-             <double>999999999.000000000000000</double>
-            </property>
            </widget>
           </item>
-          <item row="0" column="2">
-           <widget class="QDoubleSpinBox" name="m_HeaderOriginZ">
+          <item row="0" column="1">
+           <widget class="QDoubleSpinBox" name="m_HeaderSpacingY">
             <property name="decimals">
              <number>4</number>
             </property>
-            <property name="minimum">
-             <double>-999999999.000000000000000</double>
-            </property>
-            <property name="maximum">
-             <double>999999999.000000000000000</double>
-            </property>
            </widget>
           </item>
-          <item row="0" column="1">
-           <widget class="QDoubleSpinBox" name="m_HeaderOriginY">
+          <item row="0" column="2">
+           <widget class="QDoubleSpinBox" name="m_HeaderSpacingZ">
             <property name="decimals">
              <number>4</number>
             </property>
             <property name="minimum">
-             <double>-99999999.000000000000000</double>
+             <double>0.000000000000000</double>
             </property>
             <property name="maximum">
-             <double>999999999.000000000000000</double>
+             <double>99.989999999999995</double>
             </property>
            </widget>
           </item>
           <item row="1" column="0">
-           <widget class="QCommandLinkButton" name="m_ModifyOriginButton">
+           <widget class="QCommandLinkButton" name="m_ModifySpacingButton">
             <property name="enabled">
              <bool>false</bool>
             </property>
             <property name="toolTip">
              <string/>
             </property>
             <property name="statusTip">
              <string/>
             </property>
             <property name="whatsThis">
              <string notr="true"/>
             </property>
             <property name="text">
-             <string>Set new origin</string>
+             <string>Set new voxel size</string>
             </property>
            </widget>
           </item>
          </layout>
         </widget>
        </item>
-       <item row="2" column="1">
-        <spacer name="horizontalSpacer_3">
+       <item row="7" column="0">
+        <spacer name="verticalSpacer_2">
          <property name="orientation">
-          <enum>Qt::Horizontal</enum>
+          <enum>Qt::Vertical</enum>
          </property>
          <property name="sizeHint" stdset="0">
           <size>
-           <width>40</width>
-           <height>20</height>
+           <width>20</width>
+           <height>40</height>
           </size>
          </property>
         </spacer>
        </item>
-       <item row="5" column="0">
-        <widget class="QGroupBox" name="groupBox">
+       <item row="6" column="0">
+        <widget class="QGroupBox" name="groupBox_4">
+         <property name="sizePolicy">
+          <sizepolicy hsizetype="Expanding" vsizetype="Expanding">
+           <horstretch>0</horstretch>
+           <verstretch>0</verstretch>
+          </sizepolicy>
+         </property>
          <property name="title">
-          <string>Direction matrix</string>
+          <string>Measurment frame</string>
          </property>
-         <layout class="QGridLayout" name="gridLayout_3">
+         <layout class="QGridLayout" name="gridLayout">
           <property name="leftMargin">
            <number>0</number>
           </property>
-          <property name="topMargin">
-           <number>9</number>
-          </property>
           <property name="rightMargin">
            <number>0</number>
           </property>
           <property name="bottomMargin">
            <number>0</number>
           </property>
+          <item row="0" column="1">
+           <spacer name="horizontalSpacer">
+            <property name="orientation">
+             <enum>Qt::Horizontal</enum>
+            </property>
+            <property name="sizeHint" stdset="0">
+             <size>
+              <width>40</width>
+              <height>20</height>
+             </size>
+            </property>
+           </spacer>
+          </item>
           <item row="0" column="0">
-           <widget class="QTableWidget" name="m_DirectionMatrixTable">
+           <widget class="QTableWidget" name="m_MeasurementFrameTable">
             <property name="enabled">
              <bool>false</bool>
             </property>
             <property name="sizePolicy">
              <sizepolicy hsizetype="Minimum" vsizetype="Minimum">
               <horstretch>0</horstretch>
               <verstretch>0</verstretch>
              </sizepolicy>
             </property>
             <property name="minimumSize">
              <size>
               <width>0</width>
               <height>0</height>
              </size>
             </property>
             <property name="cursor" stdset="0">
              <cursorShape>IBeamCursor</cursorShape>
             </property>
             <property name="autoFillBackground">
              <bool>true</bool>
             </property>
             <property name="verticalScrollBarPolicy">
              <enum>Qt::ScrollBarAlwaysOff</enum>
             </property>
             <property name="horizontalScrollBarPolicy">
              <enum>Qt::ScrollBarAlwaysOff</enum>
             </property>
             <property name="showGrid">
              <bool>true</bool>
             </property>
             <property name="cornerButtonEnabled">
              <bool>false</bool>
             </property>
             <attribute name="horizontalHeaderVisible">
              <bool>false</bool>
             </attribute>
             <attribute name="horizontalHeaderCascadingSectionResizes">
              <bool>true</bool>
             </attribute>
             <attribute name="horizontalHeaderHighlightSections">
              <bool>true</bool>
             </attribute>
             <attribute name="horizontalHeaderMinimumSectionSize">
              <number>0</number>
             </attribute>
             <attribute name="verticalHeaderVisible">
              <bool>false</bool>
             </attribute>
             <attribute name="verticalHeaderCascadingSectionResizes">
              <bool>true</bool>
             </attribute>
             <attribute name="verticalHeaderHighlightSections">
              <bool>true</bool>
             </attribute>
             <row>
              <property name="text">
               <string>New Row</string>
              </property>
             </row>
             <row>
              <property name="text">
               <string>New Row</string>
              </property>
             </row>
             <row>
              <property name="text">
               <string>New Row</string>
              </property>
             </row>
             <column>
              <property name="text">
               <string>New Column</string>
              </property>
             </column>
             <column>
              <property name="text">
               <string>New Column</string>
              </property>
             </column>
             <column>
              <property name="text">
               <string>New Column</string>
              </property>
             </column>
            </widget>
           </item>
           <item row="1" column="0">
-           <widget class="QCommandLinkButton" name="m_ModifyDirection">
+           <widget class="QCommandLinkButton" name="m_ModifyMeasurementFrame">
             <property name="enabled">
              <bool>false</bool>
             </property>
             <property name="toolTip">
              <string>Diffusion encoding gradient directions are rotated accordingly.</string>
             </property>
             <property name="statusTip">
              <string/>
             </property>
             <property name="whatsThis">
              <string notr="true"/>
             </property>
             <property name="text">
-             <string>Apply new direction</string>
+             <string>Apply new measurement frame</string>
             </property>
            </widget>
           </item>
-          <item row="0" column="1">
-           <spacer name="horizontalSpacer_2">
-            <property name="orientation">
-             <enum>Qt::Horizontal</enum>
-            </property>
-            <property name="sizeHint" stdset="0">
-             <size>
-              <width>40</width>
-              <height>20</height>
-             </size>
-            </property>
-           </spacer>
-          </item>
          </layout>
         </widget>
        </item>
-       <item row="6" column="0">
-        <widget class="QGroupBox" name="groupBox_4">
-         <property name="sizePolicy">
-          <sizepolicy hsizetype="Expanding" vsizetype="Expanding">
-           <horstretch>0</horstretch>
-           <verstretch>0</verstretch>
-          </sizepolicy>
-         </property>
+       <item row="5" column="0">
+        <widget class="QGroupBox" name="groupBox">
          <property name="title">
-          <string>Measurment frame</string>
+          <string>Direction matrix</string>
          </property>
-         <layout class="QGridLayout" name="gridLayout">
+         <layout class="QGridLayout" name="gridLayout_3">
           <property name="leftMargin">
            <number>0</number>
           </property>
+          <property name="topMargin">
+           <number>9</number>
+          </property>
           <property name="rightMargin">
            <number>0</number>
           </property>
           <property name="bottomMargin">
            <number>0</number>
           </property>
-          <item row="0" column="1">
-           <spacer name="horizontalSpacer">
-            <property name="orientation">
-             <enum>Qt::Horizontal</enum>
-            </property>
-            <property name="sizeHint" stdset="0">
-             <size>
-              <width>40</width>
-              <height>20</height>
-             </size>
-            </property>
-           </spacer>
-          </item>
           <item row="0" column="0">
-           <widget class="QTableWidget" name="m_MeasurementFrameTable">
+           <widget class="QTableWidget" name="m_DirectionMatrixTable">
             <property name="enabled">
              <bool>false</bool>
             </property>
             <property name="sizePolicy">
              <sizepolicy hsizetype="Minimum" vsizetype="Minimum">
               <horstretch>0</horstretch>
               <verstretch>0</verstretch>
              </sizepolicy>
             </property>
             <property name="minimumSize">
              <size>
               <width>0</width>
               <height>0</height>
              </size>
             </property>
             <property name="cursor" stdset="0">
              <cursorShape>IBeamCursor</cursorShape>
             </property>
             <property name="autoFillBackground">
              <bool>true</bool>
             </property>
             <property name="verticalScrollBarPolicy">
              <enum>Qt::ScrollBarAlwaysOff</enum>
             </property>
             <property name="horizontalScrollBarPolicy">
              <enum>Qt::ScrollBarAlwaysOff</enum>
             </property>
             <property name="showGrid">
              <bool>true</bool>
             </property>
             <property name="cornerButtonEnabled">
              <bool>false</bool>
             </property>
             <attribute name="horizontalHeaderVisible">
              <bool>false</bool>
             </attribute>
             <attribute name="horizontalHeaderCascadingSectionResizes">
              <bool>true</bool>
             </attribute>
             <attribute name="horizontalHeaderHighlightSections">
              <bool>true</bool>
             </attribute>
             <attribute name="horizontalHeaderMinimumSectionSize">
              <number>0</number>
             </attribute>
             <attribute name="verticalHeaderVisible">
              <bool>false</bool>
             </attribute>
             <attribute name="verticalHeaderCascadingSectionResizes">
              <bool>true</bool>
             </attribute>
             <attribute name="verticalHeaderHighlightSections">
              <bool>true</bool>
             </attribute>
             <row>
              <property name="text">
               <string>New Row</string>
              </property>
             </row>
             <row>
              <property name="text">
               <string>New Row</string>
              </property>
             </row>
             <row>
              <property name="text">
               <string>New Row</string>
              </property>
             </row>
             <column>
              <property name="text">
               <string>New Column</string>
              </property>
             </column>
             <column>
              <property name="text">
               <string>New Column</string>
              </property>
             </column>
             <column>
              <property name="text">
               <string>New Column</string>
              </property>
             </column>
            </widget>
           </item>
           <item row="1" column="0">
-           <widget class="QCommandLinkButton" name="m_ModifyMeasurementFrame">
+           <widget class="QCommandLinkButton" name="m_ModifyDirection">
             <property name="enabled">
              <bool>false</bool>
             </property>
             <property name="toolTip">
              <string>Diffusion encoding gradient directions are rotated accordingly.</string>
             </property>
             <property name="statusTip">
              <string/>
             </property>
             <property name="whatsThis">
              <string notr="true"/>
             </property>
             <property name="text">
-             <string>Apply new measurement frame</string>
+             <string>Apply new direction</string>
             </property>
            </widget>
           </item>
+          <item row="0" column="1">
+           <spacer name="horizontalSpacer_2">
+            <property name="orientation">
+             <enum>Qt::Horizontal</enum>
+            </property>
+            <property name="sizeHint" stdset="0">
+             <size>
+              <width>40</width>
+              <height>20</height>
+             </size>
+            </property>
+           </spacer>
+          </item>
          </layout>
         </widget>
        </item>
-       <item row="4" column="0">
-        <widget class="QGroupBox" name="groupBox_7">
+       <item row="1" column="0">
+        <widget class="QGroupBox" name="groupBox_5">
          <property name="title">
-          <string>Remove or extract gradient volumes</string>
+          <string>Origin</string>
          </property>
-         <layout class="QGridLayout" name="gridLayout_18">
+         <layout class="QGridLayout" name="gridLayout_17">
+          <property name="leftMargin">
+           <number>0</number>
+          </property>
+          <property name="rightMargin">
+           <number>0</number>
+          </property>
+          <property name="bottomMargin">
+           <number>0</number>
+          </property>
           <item row="0" column="0">
-           <widget class="QCommandLinkButton" name="m_RemoveGradientButton">
-            <property name="enabled">
-             <bool>false</bool>
+           <widget class="QDoubleSpinBox" name="m_HeaderOriginX">
+            <property name="decimals">
+             <number>4</number>
             </property>
-            <property name="toolTip">
-             <string>Generate pointset displaying the gradient vectors (applied measurement frame).</string>
+            <property name="minimum">
+             <double>-999999999.000000000000000</double>
             </property>
-            <property name="statusTip">
-             <string/>
+            <property name="maximum">
+             <double>999999999.000000000000000</double>
             </property>
-            <property name="whatsThis">
-             <string notr="true"/>
+           </widget>
+          </item>
+          <item row="0" column="2">
+           <widget class="QDoubleSpinBox" name="m_HeaderOriginZ">
+            <property name="decimals">
+             <number>4</number>
             </property>
-            <property name="text">
-             <string>Remove</string>
+            <property name="minimum">
+             <double>-999999999.000000000000000</double>
+            </property>
+            <property name="maximum">
+             <double>999999999.000000000000000</double>
+            </property>
+           </widget>
+          </item>
+          <item row="0" column="1">
+           <widget class="QDoubleSpinBox" name="m_HeaderOriginY">
+            <property name="decimals">
+             <number>4</number>
+            </property>
+            <property name="minimum">
+             <double>-99999999.000000000000000</double>
+            </property>
+            <property name="maximum">
+             <double>999999999.000000000000000</double>
             </property>
            </widget>
           </item>
           <item row="1" column="0">
-           <widget class="QCommandLinkButton" name="m_ExtractGradientButton">
+           <widget class="QCommandLinkButton" name="m_ModifyOriginButton">
             <property name="enabled">
              <bool>false</bool>
             </property>
             <property name="toolTip">
-             <string>Generate pointset displaying the gradient vectors (applied measurement frame).</string>
+             <string/>
             </property>
             <property name="statusTip">
              <string/>
             </property>
             <property name="whatsThis">
              <string notr="true"/>
             </property>
             <property name="text">
-             <string>Extract</string>
+             <string>Set new origin</string>
             </property>
            </widget>
           </item>
-          <item row="1" column="1">
-           <widget class="QSpinBox" name="m_ExtractGradientBox"/>
-          </item>
-          <item row="0" column="1">
-           <widget class="QSpinBox" name="m_RemoveGradientBox"/>
-          </item>
          </layout>
         </widget>
        </item>
       </layout>
      </widget>
      <widget class="QWidget" name="tab_2">
       <attribute name="title">
        <string>Other</string>
       </attribute>
       <layout class="QGridLayout" name="gridLayout_9">
        <item row="0" column="1">
         <widget class="QCheckBox" name="m_CheckExtractAll">
          <property name="toolTip">
           <string>Create a 3D+t data set containing all b0 images as timesteps</string>
          </property>
          <property name="text">
           <string>Disable averaging</string>
          </property>
         </widget>
        </item>
        <item row="0" column="0">
         <widget class="QCommandLinkButton" name="m_ButtonExtractB0">
          <property name="enabled">
           <bool>false</bool>
          </property>
          <property name="toolTip">
           <string>If multiple baseline acquisitions are present, the default behaviour is to output an averaged image.</string>
          </property>
          <property name="statusTip">
           <string/>
          </property>
          <property name="whatsThis">
           <string notr="true"/>
          </property>
          <property name="text">
           <string>Extract baseline image</string>
          </property>
         </widget>
        </item>
        <item row="3" column="0">
         <spacer name="verticalSpacer_3">
          <property name="orientation">
           <enum>Qt::Vertical</enum>
          </property>
          <property name="sizeHint" stdset="0">
           <size>
            <width>20</width>
            <height>40</height>
           </size>
          </property>
         </spacer>
        </item>
        <item row="1" column="0">
         <widget class="QCommandLinkButton" name="m_CalcAdcButton">
          <property name="enabled">
           <bool>false</bool>
          </property>
          <property name="toolTip">
           <string>If multiple baseline acquisitions are present, the default behaviour is to output an averaged image.</string>
          </property>
          <property name="statusTip">
           <string/>
          </property>
          <property name="whatsThis">
           <string notr="true"/>
          </property>
          <property name="text">
           <string>Calculate ADC map</string>
          </property>
         </widget>
        </item>
        <item row="2" column="0">
         <widget class="QCommandLinkButton" name="m_ExtractBrainMask">
          <property name="enabled">
           <bool>false</bool>
          </property>
          <property name="toolTip">
           <string>If multiple baseline acquisitions are present, the default behaviour is to output an averaged image.</string>
          </property>
          <property name="statusTip">
           <string/>
          </property>
          <property name="whatsThis">
           <string notr="true"/>
          </property>
          <property name="text">
           <string>Estimate binary brain mask</string>
          </property>
         </widget>
        </item>
        <item row="2" column="1">
         <widget class="QSpinBox" name="m_BrainMaskIterationsBox">
          <property name="toolTip">
           <string>Maximum number of iterations.</string>
          </property>
          <property name="maximum">
           <number>10000</number>
          </property>
          <property name="value">
           <number>10000</number>
          </property>
         </widget>
        </item>
       </layout>
      </widget>
     </widget>
    </item>
   </layout>
  </widget>
  <layoutdefault spacing="6" margin="11"/>
  <customwidgets>
   <customwidget>
    <class>QmitkDataStorageComboBox</class>
    <extends>QComboBox</extends>
    <header location="global">QmitkDataStorageComboBox.h</header>
   </customwidget>
  </customwidgets>
  <tabstops>
   <tabstop>m_B_ValueMap_Rounder_SpinBox</tabstop>
   <tabstop>m_Blur</tabstop>
   <tabstop>m_targetBValueSpinBox</tabstop>
   <tabstop>m_ProjectionMethodBox</tabstop>
   <tabstop>m_ResampleTypeBox</tabstop>
   <tabstop>m_ResampleDoubleX</tabstop>
   <tabstop>m_ResampleDoubleY</tabstop>
   <tabstop>m_ResampleDoubleZ</tabstop>
   <tabstop>m_ResampleIntX</tabstop>
   <tabstop>m_ResampleIntY</tabstop>
   <tabstop>m_ResampleIntZ</tabstop>
   <tabstop>m_InterpolatorBox</tabstop>
   <tabstop>m_HeaderSpacingX</tabstop>
   <tabstop>m_HeaderSpacingY</tabstop>
   <tabstop>m_HeaderSpacingZ</tabstop>
   <tabstop>m_HeaderOriginX</tabstop>
   <tabstop>m_HeaderOriginY</tabstop>
   <tabstop>m_HeaderOriginZ</tabstop>
   <tabstop>m_DirectionMatrixTable</tabstop>
   <tabstop>m_MeasurementFrameTable</tabstop>
   <tabstop>m_CheckExtractAll</tabstop>
   <tabstop>m_BrainMaskIterationsBox</tabstop>
   <tabstop>tabWidget</tabstop>
   <tabstop>m_B_ValueMap_TableWidget</tabstop>
   <tabstop>m_CreateLengthCorrectedDwi</tabstop>
   <tabstop>m_ShowGradientsButton</tabstop>
   <tabstop>m_MirrorGradientToHalfSphereButton</tabstop>
   <tabstop>m_ReduceGradientsButton</tabstop>
   <tabstop>m_ButtonAverageGradients</tabstop>
   <tabstop>m_ProjectSignalButton</tabstop>
   <tabstop>m_NormalizeImageValuesButton</tabstop>
   <tabstop>m_MergeDwisButton</tabstop>
   <tabstop>m_ResampleImageButton</tabstop>
   <tabstop>m_ModifySpacingButton</tabstop>
   <tabstop>m_ModifyOriginButton</tabstop>
   <tabstop>m_ModifyDirection</tabstop>
   <tabstop>m_ModifyMeasurementFrame</tabstop>
   <tabstop>m_ButtonExtractB0</tabstop>
   <tabstop>m_CalcAdcButton</tabstop>
   <tabstop>m_ExtractBrainMask</tabstop>
  </tabstops>
  <resources/>
  <connections/>
 </ui>
diff --git a/Plugins/org.mitk.gui.qt.diffusionimaging/src/internal/QmitkStreamlineTrackingView.cpp b/Plugins/org.mitk.gui.qt.diffusionimaging/src/internal/QmitkStreamlineTrackingView.cpp
index da8fb53113..340a80c5b8 100644
--- a/Plugins/org.mitk.gui.qt.diffusionimaging/src/internal/QmitkStreamlineTrackingView.cpp
+++ b/Plugins/org.mitk.gui.qt.diffusionimaging/src/internal/QmitkStreamlineTrackingView.cpp
@@ -1,286 +1,286 @@
 /*===================================================================
 
 The Medical Imaging Interaction Toolkit (MITK)
 
 Copyright (c) German Cancer Research Center,
 Division of Medical and Biological Informatics.
 All rights reserved.
 
 This software is distributed WITHOUT ANY WARRANTY; without
 even the implied warranty of MERCHANTABILITY or FITNESS FOR
 A PARTICULAR PURPOSE.
 
 See LICENSE.txt or http://www.mitk.org for details.
 
 ===================================================================*/
 
 
 // Blueberry
 #include <berryISelectionService.h>
 #include <berryIWorkbenchWindow.h>
 #include <berryIStructuredSelection.h>
 
 // Qmitk
 #include "QmitkStreamlineTrackingView.h"
 #include "QmitkStdMultiWidget.h"
 
 // Qt
 #include <QMessageBox>
 
 // MITK
 #include <mitkImageToItk.h>
 #include <mitkFiberBundle.h>
 #include <mitkImageCast.h>
 #include <mitkNodePredicateDataType.h>
 #include <mitkNodePredicateNot.h>
 #include <mitkNodePredicateAnd.h>
 #include <mitkNodePredicateProperty.h>
 #include <mitkNodePredicateDimension.h>
 
 // VTK
 #include <vtkPolyData.h>
 #include <vtkPoints.h>
 #include <vtkCellArray.h>
 #include <vtkSmartPointer.h>
 #include <vtkPolyLine.h>
 #include <vtkCellData.h>
 
 
 const std::string QmitkStreamlineTrackingView::VIEW_ID = "org.mitk.views.streamlinetracking";
 const std::string id_DataManager = "org.mitk.views.datamanager";
 using namespace berry;
 
 QmitkStreamlineTrackingView::QmitkStreamlineTrackingView()
     : QmitkFunctionality()
     , m_Controls( 0 )
     , m_MultiWidget( NULL )
     , m_MaskImage( NULL )
     , m_SeedRoi( NULL )
 {
 }
 
 // Destructor
 QmitkStreamlineTrackingView::~QmitkStreamlineTrackingView()
 {
 
 }
 
 void QmitkStreamlineTrackingView::CreateQtPartControl( QWidget *parent )
 {
     if ( !m_Controls )
     {
         // create GUI widgets from the Qt Designer's .ui file
         m_Controls = new Ui::QmitkStreamlineTrackingViewControls;
         m_Controls->setupUi( parent );
         m_Controls->m_FaImageBox->SetDataStorage(this->GetDataStorage());
 
         mitk::TNodePredicateDataType<mitk::Image>::Pointer isImagePredicate = mitk::TNodePredicateDataType<mitk::Image>::New();
 
         mitk::NodePredicateProperty::Pointer isBinaryPredicate = mitk::NodePredicateProperty::New("binary", mitk::BoolProperty::New(true));
         mitk::NodePredicateNot::Pointer isNotBinaryPredicate = mitk::NodePredicateNot::New( isBinaryPredicate );
         mitk::NodePredicateAnd::Pointer isNotABinaryImagePredicate = mitk::NodePredicateAnd::New( isImagePredicate, isNotBinaryPredicate );
         mitk::NodePredicateDimension::Pointer dimensionPredicate = mitk::NodePredicateDimension::New(3);
 
         m_Controls->m_FaImageBox->SetPredicate( mitk::NodePredicateAnd::New(isNotABinaryImagePredicate, dimensionPredicate) );
 
         connect( m_Controls->commandLinkButton, SIGNAL(clicked()), this, SLOT(DoFiberTracking()) );
         connect( m_Controls->m_SeedsPerVoxelSlider, SIGNAL(valueChanged(int)), this, SLOT(OnSeedsPerVoxelChanged(int)) );
         connect( m_Controls->m_MinTractLengthSlider, SIGNAL(valueChanged(int)), this, SLOT(OnMinTractLengthChanged(int)) );
-        connect( m_Controls->m_FaThresholdSlider, SIGNAL(valueChanged(int)), this, SLOT(OnFaThresholdChanged(int)) );
+        connect( m_Controls->m_ScalarThresholdBox, SIGNAL(valueChanged(double)), this, SLOT(OnFaThresholdChanged(double)) );
         connect( m_Controls->m_AngularThresholdSlider, SIGNAL(valueChanged(int)), this, SLOT(OnAngularThresholdChanged(int)) );
         connect( m_Controls->m_StepsizeSlider, SIGNAL(valueChanged(int)), this, SLOT(OnStepsizeChanged(int)) );
         connect( m_Controls->m_fSlider, SIGNAL(valueChanged(int)), this, SLOT(OnfChanged(int)) );
         connect( m_Controls->m_gSlider, SIGNAL(valueChanged(int)), this, SLOT(OngChanged(int)) );
     }
 }
 
 void QmitkStreamlineTrackingView::OnfChanged(int value)
 {
     m_Controls->m_fLabel->setText(QString("f: ")+QString::number((float)value/100));
 }
 
 void QmitkStreamlineTrackingView::OngChanged(int value)
 {
     m_Controls->m_gLabel->setText(QString("g: ")+QString::number((float)value/100));
 }
 
 void QmitkStreamlineTrackingView::OnAngularThresholdChanged(int value)
 {
     if (value<0)
         m_Controls->m_AngularThresholdLabel->setText(QString("Min. Curvature Radius: auto"));
     else
         m_Controls->m_AngularThresholdLabel->setText(QString("Min. Curvature Radius: ")+QString::number((float)value/10)+QString("mm"));
 }
 
 void QmitkStreamlineTrackingView::OnSeedsPerVoxelChanged(int value)
 {
     m_Controls->m_SeedsPerVoxelLabel->setText(QString("Seeds per Voxel: ")+QString::number(value));
 }
 
 void QmitkStreamlineTrackingView::OnMinTractLengthChanged(int value)
 {
     m_Controls->m_MinTractLengthLabel->setText(QString("Min. Tract Length: ")+QString::number(value)+QString("mm"));
 }
 
-void QmitkStreamlineTrackingView::OnFaThresholdChanged(int value)
+void QmitkStreamlineTrackingView::OnFaThresholdChanged(double value)
 {
-    m_Controls->m_FaThresholdLabel->setText(QString("FA Threshold: ")+QString::number((float)value/100));
+    m_Controls->m_FaThresholdLabel->setText(QString("FA Threshold: ")+QString::number(value));
 }
 
 void QmitkStreamlineTrackingView::OnStepsizeChanged(int value)
 {
     if (value==0)
         m_Controls->m_StepsizeLabel->setText(QString("Stepsize: auto"));
     else
         m_Controls->m_StepsizeLabel->setText(QString("Stepsize: ")+QString::number((float)value/10)+QString("mm"));
 }
 
 void QmitkStreamlineTrackingView::StdMultiWidgetAvailable (QmitkStdMultiWidget &stdMultiWidget)
 {
     m_MultiWidget = &stdMultiWidget;
 }
 
 
 void QmitkStreamlineTrackingView::StdMultiWidgetNotAvailable()
 {
     m_MultiWidget = NULL;
 }
 
 void QmitkStreamlineTrackingView::OnSelectionChanged( std::vector<mitk::DataNode*> nodes )
 {
     m_TensorImageNodes.clear();
     m_TensorImages.clear();
     m_SeedRoi = NULL;
     m_MaskImage = NULL;
     m_Controls->m_TensorImageLabel->setText("<font color='red'>mandatory</font>");
     m_Controls->m_RoiImageLabel->setText("<font color='grey'>optional</font>");
     m_Controls->m_MaskImageLabel->setText("<font color='grey'>optional</font>");
 
     for( std::vector<mitk::DataNode*>::iterator it = nodes.begin(); it != nodes.end(); ++it )
     {
         mitk::DataNode::Pointer node = *it;
 
         if( node.IsNotNull() && dynamic_cast<mitk::Image*>(node->GetData()) )
         {
             if( dynamic_cast<mitk::TensorImage*>(node->GetData()) )
             {
                 m_TensorImageNodes.push_back(node);
                 m_TensorImages.push_back(dynamic_cast<mitk::TensorImage*>(node->GetData()));
             }
             else
             {
                 bool isBinary = false;
                 node->GetPropertyValue<bool>("binary", isBinary);
                 if (isBinary && m_SeedRoi.IsNull())
                 {
                     m_SeedRoi = dynamic_cast<mitk::Image*>(node->GetData());
                     m_Controls->m_RoiImageLabel->setText(node->GetName().c_str());
                 }
                 else if (isBinary)
                 {
                     m_MaskImage = dynamic_cast<mitk::Image*>(node->GetData());
                     m_Controls->m_MaskImageLabel->setText(node->GetName().c_str());
                 }
             }
         }
     }
 
     if(!m_TensorImageNodes.empty())
     {
         if (m_TensorImageNodes.size()>1)
             m_Controls->m_TensorImageLabel->setText(m_TensorImageNodes.size()+" tensor images selected");
         else
             m_Controls->m_TensorImageLabel->setText(m_TensorImageNodes.at(0)->GetName().c_str());
         m_Controls->m_InputData->setTitle("Input Data");
         m_Controls->commandLinkButton->setEnabled(true);
     }
     else
     {
         m_Controls->m_InputData->setTitle("Please Select Input Data");
         m_Controls->commandLinkButton->setEnabled(false);
     }
 }
 
 
 
 void QmitkStreamlineTrackingView::DoFiberTracking()
 {
     if (m_TensorImages.empty())
         return;
 
     typedef itk::Image< itk::DiffusionTensor3D<float>, 3> TensorImageType;
     typedef mitk::ImageToItk<TensorImageType> CastType;
     typedef mitk::ImageToItk<ItkUCharImageType> CastType2;
 
     typedef itk::StreamlineTrackingFilter< float > FilterType;
     FilterType::Pointer filter = FilterType::New();
 
     for (int i=0; i<(int)m_TensorImages.size(); i++)
     {
         CastType::Pointer caster = CastType::New();
         caster->SetInput(m_TensorImages.at(i));
         caster->Update();
         filter->SetInput(i, caster->GetOutput());
     }
 
     if (m_Controls->m_UseFaImage->isChecked())
     {
         mitk::ImageToItk<ItkFloatImageType>::Pointer floatCast = mitk::ImageToItk<ItkFloatImageType>::New();
         floatCast->SetInput(dynamic_cast<mitk::Image*>(m_Controls->m_FaImageBox->GetSelectedNode()->GetData()));
         floatCast->Update();
         filter->SetFaImage(floatCast->GetOutput());
     }
 
     //filter->SetNumberOfThreads(1);
     filter->SetSeedsPerVoxel(m_Controls->m_SeedsPerVoxelSlider->value());
-    filter->SetFaThreshold((float)m_Controls->m_FaThresholdSlider->value()/100);
+    filter->SetFaThreshold(m_Controls->m_ScalarThresholdBox->value());
     filter->SetMinCurvatureRadius((float)m_Controls->m_AngularThresholdSlider->value()/10);
     filter->SetStepSize((float)m_Controls->m_StepsizeSlider->value()/10);
     filter->SetF((float)m_Controls->m_fSlider->value()/100);
     filter->SetG((float)m_Controls->m_gSlider->value()/100);
     filter->SetInterpolate(m_Controls->m_InterpolationBox->isChecked());
     filter->SetMinTractLength(m_Controls->m_MinTractLengthSlider->value());
 
     if (m_SeedRoi.IsNotNull())
     {
         ItkUCharImageType::Pointer mask = ItkUCharImageType::New();
         mitk::CastToItkImage(m_SeedRoi, mask);
         filter->SetSeedImage(mask);
     }
 
     if (m_MaskImage.IsNotNull())
     {
         ItkUCharImageType::Pointer mask = ItkUCharImageType::New();
         mitk::CastToItkImage(m_MaskImage, mask);
         filter->SetMaskImage(mask);
     }
 
     filter->Update();
 
     vtkSmartPointer<vtkPolyData> fiberBundle = filter->GetFiberPolyData();
     if ( fiberBundle->GetNumberOfLines()==0 )
     {
         QMessageBox warnBox;
         warnBox.setWindowTitle("Warning");
         warnBox.setText("No fiberbundle was generated!");
         warnBox.setDetailedText("No fibers were generated using the parameters: \n\n" + m_Controls->m_FaThresholdLabel->text() + "\n" + m_Controls->m_AngularThresholdLabel->text() + "\n" + m_Controls->m_fLabel->text() + "\n" + m_Controls->m_gLabel->text() + "\n" + m_Controls->m_StepsizeLabel->text() + "\n" + m_Controls->m_MinTractLengthLabel->text() + "\n" + m_Controls->m_SeedsPerVoxelLabel->text() + "\n\nPlease check your parametersettings.");
         warnBox.setIcon(QMessageBox::Warning);
         warnBox.exec();
         return;
     }
     mitk::FiberBundle::Pointer fib = mitk::FiberBundle::New(fiberBundle);
     fib->SetReferenceGeometry(dynamic_cast<mitk::Image*>(m_TensorImageNodes.at(0)->GetData())->GetGeometry());
     if (m_Controls->m_ResampleFibersBox->isChecked())
         fib->Compress(m_Controls->m_FiberErrorBox->value());
 
     mitk::DataNode::Pointer node = mitk::DataNode::New();
     node->SetData(fib);
     QString name("FiberBundle_");
     name += m_TensorImageNodes.at(0)->GetName().c_str();
     name += "_Streamline";
     node->SetName(name.toStdString());
     node->SetVisibility(true);
     GetDataStorage()->Add(node, m_TensorImageNodes.at(0));
 }
 
 
diff --git a/Plugins/org.mitk.gui.qt.diffusionimaging/src/internal/QmitkStreamlineTrackingView.h b/Plugins/org.mitk.gui.qt.diffusionimaging/src/internal/QmitkStreamlineTrackingView.h
index fb4407ab0f..e0ec22fa08 100644
--- a/Plugins/org.mitk.gui.qt.diffusionimaging/src/internal/QmitkStreamlineTrackingView.h
+++ b/Plugins/org.mitk.gui.qt.diffusionimaging/src/internal/QmitkStreamlineTrackingView.h
@@ -1,90 +1,90 @@
 /*===================================================================
 
 The Medical Imaging Interaction Toolkit (MITK)
 
 Copyright (c) German Cancer Research Center,
 Division of Medical and Biological Informatics.
 All rights reserved.
 
 This software is distributed WITHOUT ANY WARRANTY; without
 even the implied warranty of MERCHANTABILITY or FITNESS FOR
 A PARTICULAR PURPOSE.
 
 See LICENSE.txt or http://www.mitk.org for details.
 
 ===================================================================*/
 
 #ifndef QmitkStreamlineTrackingView_h
 #define QmitkStreamlineTrackingView_h
 
 #include <QmitkFunctionality.h>
 
 #include "ui_QmitkStreamlineTrackingViewControls.h"
 
 #include <mitkTensorImage.h>
 #include <mitkDataStorage.h>
 #include <mitkImage.h>
 #include <itkImage.h>
 #include <itkStreamlineTrackingFilter.h>
 
 
 /*!
 \brief View for tensor based deterministic streamline fiber tracking.
 \sa QmitkFunctionality
 \ingroup Functionalities
 */
 class QmitkStreamlineTrackingView : public QmitkFunctionality
 {
     // this is needed for all Qt objects that should have a Qt meta-object
     // (everything that derives from QObject and wants to have signal/slots)
     Q_OBJECT
 
 public:
 
     static const std::string VIEW_ID;
 
     typedef itk::Image< unsigned char, 3 > ItkUCharImageType;
     typedef itk::Image< float, 3 > ItkFloatImageType;
 
     QmitkStreamlineTrackingView();
     virtual ~QmitkStreamlineTrackingView();
 
     virtual void CreateQtPartControl(QWidget *parent);
 
     virtual void StdMultiWidgetAvailable (QmitkStdMultiWidget &stdMultiWidget);
     virtual void StdMultiWidgetNotAvailable();
 
 protected slots:
 
     void DoFiberTracking();   ///< start fiber tracking
 
 protected:
 
     /// \brief called by QmitkFunctionality when DataManager's selection has changed
     virtual void OnSelectionChanged( std::vector<mitk::DataNode*> nodes );
     Ui::QmitkStreamlineTrackingViewControls* m_Controls;
     QmitkStdMultiWidget* m_MultiWidget;
 
 protected slots:
 
     /** update labels if parameters have changed */
     void OnSeedsPerVoxelChanged(int value);
     void OnMinTractLengthChanged(int value);
-    void OnFaThresholdChanged(int value);
+    void OnFaThresholdChanged(double value);
     void OnAngularThresholdChanged(int value);
     void OnfChanged(int value);
     void OngChanged(int value);
     void OnStepsizeChanged(int value);
 
 private:
 
     mitk::Image::Pointer          m_MaskImage;        ///< abort tracking if leaving mask
     mitk::Image::Pointer          m_SeedRoi;          ///< binary image defining seed voxels for tracking process
     std::vector< mitk::DataNode::Pointer > m_TensorImageNodes; ///< input images
     std::vector< mitk::TensorImage::Pointer > m_TensorImages; ///< input image datanode
 };
 
 
 
 #endif // _QMITKFIBERTRACKINGVIEW_H_INCLUDED
 
diff --git a/Plugins/org.mitk.gui.qt.diffusionimaging/src/internal/QmitkStreamlineTrackingViewControls.ui b/Plugins/org.mitk.gui.qt.diffusionimaging/src/internal/QmitkStreamlineTrackingViewControls.ui
index a15bdec4bf..a08598a6ac 100644
--- a/Plugins/org.mitk.gui.qt.diffusionimaging/src/internal/QmitkStreamlineTrackingViewControls.ui
+++ b/Plugins/org.mitk.gui.qt.diffusionimaging/src/internal/QmitkStreamlineTrackingViewControls.ui
@@ -1,434 +1,434 @@
 <?xml version="1.0" encoding="UTF-8"?>
 <ui version="4.0">
  <class>QmitkStreamlineTrackingViewControls</class>
  <widget class="QWidget" name="QmitkStreamlineTrackingViewControls">
   <property name="geometry">
    <rect>
     <x>0</x>
     <y>0</y>
     <width>382</width>
     <height>538</height>
    </rect>
   </property>
   <property name="minimumSize">
    <size>
     <width>0</width>
     <height>0</height>
    </size>
   </property>
   <property name="windowTitle">
    <string>QmitkTemplate</string>
   </property>
   <layout class="QGridLayout" name="gridLayout_3">
    <property name="topMargin">
     <number>3</number>
    </property>
    <property name="bottomMargin">
     <number>3</number>
    </property>
    <property name="spacing">
     <number>0</number>
    </property>
    <item row="8" column="0">
     <spacer name="spacer1">
      <property name="orientation">
       <enum>Qt::Vertical</enum>
      </property>
      <property name="sizeType">
       <enum>QSizePolicy::Expanding</enum>
      </property>
      <property name="sizeHint" stdset="0">
       <size>
        <width>20</width>
        <height>220</height>
       </size>
      </property>
     </spacer>
    </item>
    <item row="1" column="0">
     <widget class="QCommandLinkButton" name="commandLinkButton">
      <property name="enabled">
       <bool>false</bool>
      </property>
      <property name="text">
       <string>Start Tractography</string>
      </property>
     </widget>
    </item>
    <item row="5" column="0">
     <widget class="QGroupBox" name="groupBox_2">
      <property name="title">
       <string>Parameters</string>
      </property>
      <layout class="QGridLayout" name="gridLayout_2">
       <item row="4" column="1">
        <widget class="QSlider" name="m_gSlider">
         <property name="toolTip">
          <string>Weighting factor between input vector (g=0) and tensor deflection (g=1 equals TEND tracking)</string>
         </property>
         <property name="minimum">
          <number>0</number>
         </property>
         <property name="maximum">
          <number>100</number>
         </property>
         <property name="value">
          <number>0</number>
         </property>
         <property name="orientation">
          <enum>Qt::Horizontal</enum>
         </property>
        </widget>
       </item>
       <item row="5" column="1">
        <widget class="QSlider" name="m_StepsizeSlider">
         <property name="toolTip">
          <string>Stepsize in mm (auto = 0.1*minimal spacing)</string>
         </property>
         <property name="minimum">
          <number>0</number>
         </property>
         <property name="maximum">
          <number>100</number>
         </property>
         <property name="value">
          <number>0</number>
         </property>
         <property name="orientation">
          <enum>Qt::Horizontal</enum>
         </property>
        </widget>
       </item>
       <item row="2" column="1">
        <widget class="QSlider" name="m_AngularThresholdSlider">
         <property name="toolTip">
          <string>Minimally allowed curcature radius (in mm, interpolated auto = 0.5 minimal spacing, noninterpolated auto = 0.5 * minimal spacing)</string>
         </property>
         <property name="minimum">
          <number>-1</number>
         </property>
         <property name="maximum">
          <number>50</number>
         </property>
         <property name="value">
          <number>-1</number>
         </property>
         <property name="orientation">
          <enum>Qt::Horizontal</enum>
         </property>
        </widget>
       </item>
       <item row="6" column="0">
        <widget class="QLabel" name="m_MinTractLengthLabel">
         <property name="toolTip">
          <string/>
         </property>
         <property name="text">
          <string>Min. Tract Length: 20mm</string>
         </property>
        </widget>
       </item>
       <item row="1" column="0">
        <widget class="QLabel" name="m_FaThresholdLabel">
         <property name="toolTip">
          <string/>
         </property>
         <property name="text">
          <string>FA Threshold: 0.2</string>
         </property>
        </widget>
       </item>
       <item row="4" column="0">
        <widget class="QLabel" name="m_gLabel">
         <property name="toolTip">
          <string/>
         </property>
         <property name="text">
          <string>g: 0</string>
         </property>
        </widget>
       </item>
       <item row="8" column="0">
        <spacer name="horizontalSpacer">
         <property name="orientation">
          <enum>Qt::Horizontal</enum>
         </property>
         <property name="sizeType">
          <enum>QSizePolicy::Fixed</enum>
         </property>
         <property name="sizeHint" stdset="0">
          <size>
           <width>200</width>
           <height>0</height>
          </size>
         </property>
        </spacer>
       </item>
       <item row="7" column="0">
        <widget class="QLabel" name="m_SeedsPerVoxelLabel">
         <property name="toolTip">
          <string/>
         </property>
         <property name="text">
          <string>Seeds per Voxel: 1</string>
         </property>
        </widget>
       </item>
       <item row="7" column="1">
        <widget class="QSlider" name="m_SeedsPerVoxelSlider">
         <property name="toolTip">
          <string>Number of tracts started in each voxel of the seed ROI.</string>
         </property>
         <property name="minimum">
          <number>1</number>
         </property>
         <property name="maximum">
          <number>100</number>
         </property>
         <property name="orientation">
          <enum>Qt::Horizontal</enum>
         </property>
        </widget>
       </item>
       <item row="5" column="0">
        <widget class="QLabel" name="m_StepsizeLabel">
         <property name="toolTip">
          <string/>
         </property>
         <property name="text">
          <string>Step Size: auto</string>
         </property>
        </widget>
       </item>
       <item row="3" column="1">
        <widget class="QSlider" name="m_fSlider">
         <property name="toolTip">
          <string>Weighting factor between first eigenvector (f=1 equals FACT tracking) and input vector dependent direction (f=0).</string>
         </property>
         <property name="minimum">
          <number>0</number>
         </property>
         <property name="maximum">
          <number>100</number>
         </property>
         <property name="value">
          <number>100</number>
         </property>
         <property name="orientation">
          <enum>Qt::Horizontal</enum>
         </property>
        </widget>
       </item>
-      <item row="1" column="1">
-       <widget class="QSlider" name="m_FaThresholdSlider">
-        <property name="toolTip">
-         <string>Fractional Anisotropy Threshold</string>
-        </property>
-        <property name="minimum">
-         <number>0</number>
-        </property>
-        <property name="maximum">
-         <number>100</number>
-        </property>
-        <property name="value">
-         <number>20</number>
-        </property>
-        <property name="orientation">
-         <enum>Qt::Horizontal</enum>
-        </property>
-       </widget>
-      </item>
       <item row="6" column="1">
        <widget class="QSlider" name="m_MinTractLengthSlider">
         <property name="toolTip">
          <string>Minimum tract length in mm.</string>
         </property>
         <property name="minimum">
          <number>0</number>
         </property>
         <property name="maximum">
          <number>500</number>
         </property>
         <property name="value">
          <number>20</number>
         </property>
         <property name="orientation">
          <enum>Qt::Horizontal</enum>
         </property>
        </widget>
       </item>
       <item row="9" column="0">
        <widget class="QCheckBox" name="m_InterpolationBox">
         <property name="toolTip">
          <string>Default is nearest neighbor interpolation.</string>
         </property>
         <property name="text">
          <string>Enable Trilinear Interpolation</string>
         </property>
         <property name="checked">
          <bool>true</bool>
         </property>
        </widget>
       </item>
       <item row="3" column="0">
        <widget class="QLabel" name="m_fLabel">
         <property name="toolTip">
          <string/>
         </property>
         <property name="text">
          <string>f: 1</string>
         </property>
        </widget>
       </item>
       <item row="2" column="0">
        <widget class="QLabel" name="m_AngularThresholdLabel">
         <property name="toolTip">
          <string/>
         </property>
         <property name="text">
          <string>Min. Curvature Radius: auto</string>
         </property>
        </widget>
       </item>
       <item row="10" column="0">
        <widget class="QCheckBox" name="m_ResampleFibersBox">
         <property name="toolTip">
          <string>Resample fibers using the specified error constraint.</string>
         </property>
         <property name="text">
          <string>Compress Fibers</string>
         </property>
         <property name="checked">
          <bool>false</bool>
         </property>
        </widget>
       </item>
       <item row="10" column="1">
        <widget class="QDoubleSpinBox" name="m_FiberErrorBox">
         <property name="focusPolicy">
          <enum>Qt::StrongFocus</enum>
         </property>
         <property name="toolTip">
          <string>Maximum error in mm.</string>
         </property>
         <property name="decimals">
          <number>3</number>
         </property>
         <property name="maximum">
          <double>10.000000000000000</double>
         </property>
         <property name="singleStep">
          <double>0.010000000000000</double>
         </property>
         <property name="value">
          <double>0.100000000000000</double>
         </property>
        </widget>
       </item>
+      <item row="1" column="1">
+       <widget class="QDoubleSpinBox" name="m_ScalarThresholdBox">
+        <property name="decimals">
+         <number>5</number>
+        </property>
+        <property name="maximum">
+         <double>1.000000000000000</double>
+        </property>
+        <property name="singleStep">
+         <double>0.100000000000000</double>
+        </property>
+        <property name="value">
+         <double>0.200000000000000</double>
+        </property>
+       </widget>
+      </item>
      </layout>
     </widget>
    </item>
    <item row="0" column="0">
     <widget class="QGroupBox" name="m_InputData">
      <property name="title">
       <string>Please Select Input Data</string>
      </property>
      <layout class="QGridLayout" name="gridLayout">
       <item row="2" column="1">
        <widget class="QLabel" name="m_MaskImageLabel">
         <property name="text">
          <string>&lt;html&gt;&lt;head/&gt;&lt;body&gt;&lt;p&gt;&lt;span style=&quot; color:#969696;&quot;&gt;optional&lt;/span&gt;&lt;/p&gt;&lt;/body&gt;&lt;/html&gt;</string>
         </property>
         <property name="wordWrap">
          <bool>true</bool>
         </property>
        </widget>
       </item>
       <item row="4" column="1">
        <widget class="QmitkDataStorageComboBox" name="m_FaImageBox">
+        <property name="sizeAdjustPolicy">
+         <enum>QComboBox::AdjustToMinimumContentsLength</enum>
+        </property>
         <item>
          <property name="text">
           <string>-</string>
          </property>
         </item>
        </widget>
       </item>
       <item row="1" column="1">
        <widget class="QLabel" name="m_RoiImageLabel">
         <property name="text">
          <string>&lt;html&gt;&lt;head/&gt;&lt;body&gt;&lt;p&gt;&lt;span style=&quot; color:#969696;&quot;&gt;optional&lt;/span&gt;&lt;/p&gt;&lt;/body&gt;&lt;/html&gt;</string>
         </property>
         <property name="wordWrap">
          <bool>true</bool>
         </property>
        </widget>
       </item>
       <item row="2" column="0">
        <widget class="QLabel" name="label_7">
         <property name="toolTip">
          <string>Only track insida mask area.</string>
         </property>
         <property name="text">
          <string>Mask Image:</string>
         </property>
        </widget>
       </item>
       <item row="1" column="0">
        <widget class="QLabel" name="label_6">
         <property name="toolTip">
          <string>Binary seed ROI. If not specified, the whole image area is seeded.</string>
         </property>
         <property name="text">
          <string>Seed ROI:</string>
         </property>
        </widget>
       </item>
       <item row="0" column="1">
        <widget class="QLabel" name="m_TensorImageLabel">
         <property name="text">
          <string>&lt;html&gt;&lt;head/&gt;&lt;body&gt;&lt;p&gt;&lt;span style=&quot; color:#ff0000;&quot;&gt;mandatory&lt;/span&gt;&lt;/p&gt;&lt;/body&gt;&lt;/html&gt;</string>
         </property>
         <property name="wordWrap">
          <bool>true</bool>
         </property>
        </widget>
       </item>
       <item row="0" column="0">
        <widget class="QLabel" name="label_2">
         <property name="toolTip">
          <string>Input DTI</string>
         </property>
         <property name="text">
          <string>Tensor Image:</string>
         </property>
        </widget>
       </item>
       <item row="4" column="0">
        <widget class="QCheckBox" name="m_UseFaImage">
         <property name="toolTip">
          <string>Check to use selected FA image instead of internally calculated one. Recommended for multi-tensor tractography.</string>
         </property>
         <property name="text">
          <string>FA image</string>
         </property>
         <property name="checked">
          <bool>false</bool>
         </property>
        </widget>
       </item>
      </layout>
     </widget>
    </item>
   </layout>
  </widget>
  <layoutdefault spacing="6" margin="11"/>
  <customwidgets>
   <customwidget>
    <class>QmitkDataStorageComboBox</class>
    <extends>QComboBox</extends>
    <header location="global">QmitkDataStorageComboBox.h</header>
   </customwidget>
  </customwidgets>
  <resources/>
  <connections/>
 </ui>