diff --git a/Modules/DiffusionImaging/FiberTracking/Algorithms/itkTractsToDWIImageFilter.cpp b/Modules/DiffusionImaging/FiberTracking/Algorithms/itkTractsToDWIImageFilter.cpp
index 5c496d7df9..0208fac36e 100644
--- a/Modules/DiffusionImaging/FiberTracking/Algorithms/itkTractsToDWIImageFilter.cpp
+++ b/Modules/DiffusionImaging/FiberTracking/Algorithms/itkTractsToDWIImageFilter.cpp
@@ -1,663 +1,651 @@
 /*===================================================================
 
 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 <mitkGibbsRingingArtifact.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>
 
 namespace itk
 {
 TractsToDWIImageFilter::TractsToDWIImageFilter()
     : m_CircleDummy(false)
     , m_VolumeAccuracy(10)
     , m_Upsampling(1)
     , m_NumberOfRepetitions(1)
     , m_EnforcePureFiberVoxels(false)
     , m_InterpolationShrink(10)
     , m_FiberRadius(20)
     , m_SignalScale(300)
     , m_kOffset(0)
     , m_tLine(1)
 {
     m_Spacing.Fill(2.5); m_Origin.Fill(0.0);
     m_DirectionMatrix.SetIdentity();
     m_ImageRegion.SetSize(0, 10);
     m_ImageRegion.SetSize(1, 10);
     m_ImageRegion.SetSize(2, 10);
 }
 
 TractsToDWIImageFilter::~TractsToDWIImageFilter()
 {
 
 }
 
 std::vector< TractsToDWIImageFilter::DoubleDwiType::Pointer > TractsToDWIImageFilter::DoKspaceStuff( std::vector< DoubleDwiType::Pointer >& images )
 {
     // create slice object
     SliceType::Pointer slice = SliceType::New();
     ImageRegion<2> region;
     region.SetSize(0, m_UpsampledImageRegion.GetSize()[0]);
     region.SetSize(1, m_UpsampledImageRegion.GetSize()[1]);
     slice->SetLargestPossibleRegion( region );
     slice->SetBufferedRegion( region );
     slice->SetRequestedRegion( region );
     slice->Allocate();
 
     // frequency map slice
     SliceType::Pointer fMap = NULL;
     if (m_FrequencyMap.IsNotNull())
     {
         fMap = SliceType::New();
         ImageRegion<2> region;
         region.SetSize(0, m_UpsampledImageRegion.GetSize()[0]);
         region.SetSize(1, m_UpsampledImageRegion.GetSize()[1]);
         fMap->SetLargestPossibleRegion( region );
         fMap->SetBufferedRegion( region );
         fMap->SetRequestedRegion( region );
         fMap->Allocate();
     }
 
     boost::progress_display disp(images.size()*images[0]->GetVectorLength()*images[0]->GetLargestPossibleRegion().GetSize(2));
     std::vector< DoubleDwiType::Pointer > outImages;
     for (int i=0; i<images.size(); i++)
     {
         DoubleDwiType::Pointer image = images.at(i);
         DoubleDwiType::Pointer newImage = DoubleDwiType::New();
         newImage->SetSpacing( m_Spacing );
         newImage->SetOrigin( m_Origin );
         newImage->SetDirection( m_DirectionMatrix );
         newImage->SetLargestPossibleRegion( m_ImageRegion );
         newImage->SetBufferedRegion( m_ImageRegion );
         newImage->SetRequestedRegion( m_ImageRegion );
         newImage->SetVectorLength( image->GetVectorLength() );
         newImage->Allocate();
 
         DiffusionSignalModel<double>* signalModel;
         if (i<m_FiberModels.size())
             signalModel = m_FiberModels.at(i);
         else
             signalModel = m_NonFiberModels.at(i-m_FiberModels.size());
 
         for (int g=0; g<image->GetVectorLength(); g++)
             for (int z=0; z<image->GetLargestPossibleRegion().GetSize(2); z++)
             {
                 ++disp;
 
                 // extract slice from channel g
                 for (int y=0; y<image->GetLargestPossibleRegion().GetSize(1); y++)
                     for (int x=0; x<image->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;
 
                         SliceType::PixelType pix2D = image->GetPixel(index3D)[g];
                         slice->SetPixel(index2D, pix2D);
 
                         if (fMap.IsNotNull())
                             fMap->SetPixel(index2D, m_FrequencyMap->GetPixel(index3D));
                     }
 
                 // fourier transform slice
                 ComplexSliceType::Pointer fSlice;
-
-//                itk::FFTRealToComplexConjugateImageFilter< SliceType::PixelType, 2 >::Pointer fft = itk::FFTRealToComplexConjugateImageFilter< SliceType::PixelType, 2 >::New();
-//                fft->SetInput(slice);
-//                fft->Update();
-//                fSlice = fft->GetOutput();
-
                 itk::KspaceImageFilter< SliceType::PixelType >::Pointer idft = itk::KspaceImageFilter< SliceType::PixelType >::New();
                 idft->SetInput(slice);
                 idft->SetkOffset(m_kOffset);
                 idft->SettLine(m_tLine);
                 idft->SetFrequencyMap(fMap);
                 idft->Update();
 
                 fSlice = idft->GetOutput();
                 fSlice = RearrangeSlice(fSlice);
 
                 // add artifacts
                 for (int a=0; a<m_KspaceArtifacts.size(); a++)
                 {
                     m_KspaceArtifacts.at(a)->SetT2(signalModel->GetT2());
                     fSlice = m_KspaceArtifacts.at(a)->AddArtifact(fSlice);
                 }
 
                 // save k-space slice of s0 image
                 if (g==m_FiberModels.at(0)->GetFirstBaselineIndex())
                     for (int y=0; y<fSlice->GetLargestPossibleRegion().GetSize(1); y++)
                         for (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;
                             double kpix = sqrt(fSlice->GetPixel(index2D).real()*fSlice->GetPixel(index2D).real()+fSlice->GetPixel(index2D).imag()*fSlice->GetPixel(index2D).imag());
                             m_KspaceImage->SetPixel(index3D, m_KspaceImage->GetPixel(index3D)+kpix);
                         }
 
                 // inverse 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();
 
-//                itk::FFTComplexConjugateToRealImageFilter< SliceType::PixelType, 2 >::Pointer ifft = itk::FFTComplexConjugateToRealImageFilter< SliceType::PixelType, 2 >::New();
-//                ifft->SetInput(fSlice);
-//                ifft->Update();
-//                newSlice = ifft->GetOutput();
-
                 // put slice back into channel g
                 for (int y=0; y<fSlice->GetLargestPossibleRegion().GetSize(1); y++)
                     for (int x=0; x<fSlice->GetLargestPossibleRegion().GetSize(0); x++)
                     {
                         DoubleDwiType::IndexType index3D;
                         index3D[0]=x; index3D[1]=y; index3D[2]=z;
                         DoubleDwiType::PixelType pix3D = newImage->GetPixel(index3D);
                         SliceType::IndexType index2D;
                         index2D[0]=x; index2D[1]=y;
 
                         pix3D[g] = newSlice->GetPixel(index2D);
                         newImage->SetPixel(index3D, pix3D);
                     }
             }
         outImages.push_back(newImage);
     }
     return outImages;
 }
 
 TractsToDWIImageFilter::ComplexSliceType::Pointer TractsToDWIImageFilter::RearrangeSlice(ComplexSliceType::Pointer slice)
 {
     ImageRegion<2> region = slice->GetLargestPossibleRegion();
     ComplexSliceType::Pointer rearrangedSlice = ComplexSliceType::New();
     rearrangedSlice->SetLargestPossibleRegion( region );
     rearrangedSlice->SetBufferedRegion( region );
     rearrangedSlice->SetRequestedRegion( region );
     rearrangedSlice->Allocate();
 
     int xHalf = region.GetSize(0)/2;
     int yHalf = region.GetSize(1)/2;
 
     for (int y=0; y<region.GetSize(1); y++)
         for (int x=0; x<region.GetSize(0); x++)
         {
             SliceType::IndexType idx;
             idx[0]=x; idx[1]=y;
             vcl_complex< double > pix = slice->GetPixel(idx);
 
             if( idx[0] <  xHalf )
                 idx[0] = idx[0] + xHalf;
             else
                 idx[0] = idx[0] - xHalf;
 
             if( idx[1] <  yHalf )
                 idx[1] = idx[1] + yHalf;
             else
                 idx[1] = idx[1] - yHalf;
 
             rearrangedSlice->SetPixel(idx, pix);
         }
 
     return rearrangedSlice;
 }
 
 void TractsToDWIImageFilter::GenerateData()
 {
     // check input data
     if (m_FiberBundle.IsNull())
         itkExceptionMacro("Input fiber bundle is NULL!");
 
     int numFibers = m_FiberBundle->GetNumFibers();
     if (numFibers<=0)
         itkExceptionMacro("Input fiber bundle contains no fibers!");
 
     if (m_FiberModels.empty())
         itkExceptionMacro("No diffusion model for fiber compartments defined!");
 
     if (m_NonFiberModels.empty())
         itkExceptionMacro("No diffusion model for non-fiber compartments defined!");
 
     int baselineIndex = m_FiberModels[0]->GetFirstBaselineIndex();
     if (baselineIndex<0)
         itkExceptionMacro("No baseline index found!");
 
     // determine k-space undersampling
     for (int i=0; i<m_KspaceArtifacts.size(); i++)
         if ( dynamic_cast<mitk::GibbsRingingArtifact<double>*>(m_KspaceArtifacts.at(i)) )
             m_Upsampling = dynamic_cast<mitk::GibbsRingingArtifact<double>*>(m_KspaceArtifacts.at(i))->GetKspaceCropping();
     if (m_Upsampling<1)
         m_Upsampling = 1;
 
     if (m_TissueMask.IsNotNull())
     {
         // use input tissue mask
         m_Spacing = m_TissueMask->GetSpacing();
         m_Origin = m_TissueMask->GetOrigin();
         m_DirectionMatrix = m_TissueMask->GetDirection();
         m_ImageRegion = m_TissueMask->GetLargestPossibleRegion();
 
         if (m_Upsampling>1)
         {
             ImageRegion<3> region = m_ImageRegion;
             region.SetSize(0, m_ImageRegion.GetSize(0)*m_Upsampling);
             region.SetSize(1, m_ImageRegion.GetSize(1)*m_Upsampling);
             mitk::Vector3D spacing = m_Spacing;
             spacing[0] /= m_Upsampling;
             spacing[1] /= m_Upsampling;
             itk::RescaleIntensityImageFilter<ItkUcharImgType,ItkUcharImgType>::Pointer rescaler = itk::RescaleIntensityImageFilter<ItkUcharImgType,ItkUcharImgType>::New();
             rescaler->SetInput(0,m_TissueMask);
             rescaler->SetOutputMaximum(100);
             rescaler->SetOutputMinimum(0);
             rescaler->Update();
 
             itk::ResampleImageFilter<ItkUcharImgType, ItkUcharImgType>::Pointer resampler = itk::ResampleImageFilter<ItkUcharImgType, ItkUcharImgType>::New();
             resampler->SetInput(rescaler->GetOutput());
             resampler->SetOutputParametersFromImage(m_TissueMask);
             resampler->SetSize(region.GetSize());
             resampler->SetOutputSpacing(spacing);
             resampler->Update();
             m_TissueMask = resampler->GetOutput();
         }
         MITK_INFO << "Using tissue mask";
     }
 
     // initialize output dwi image
     OutputImageType::Pointer outImage = OutputImageType::New();
     outImage->SetSpacing( m_Spacing );
     outImage->SetOrigin( m_Origin );
     outImage->SetDirection( m_DirectionMatrix );
     outImage->SetLargestPossibleRegion( m_ImageRegion );
     outImage->SetBufferedRegion( m_ImageRegion );
     outImage->SetRequestedRegion( m_ImageRegion );
     outImage->SetVectorLength( m_FiberModels[0]->GetNumGradients() );
     outImage->Allocate();
     OutputImageType::PixelType temp;
     temp.SetSize(m_FiberModels[0]->GetNumGradients());
     temp.Fill(0.0);
     outImage->FillBuffer(temp);
 
     // is input slize size a power of two?
     int x=m_ImageRegion.GetSize(0); int y=m_ImageRegion.GetSize(1);
     if ( x%2 == 1 )
         x += 1;
     if ( y%2 == 1 )
         y += 1;
 
     // if not, adjust size and dimension (needed for FFT); zero-padding
     if (x!=m_ImageRegion.GetSize(0))
     {
         MITK_INFO << "Adjusting image width: " << m_ImageRegion.GetSize(0) << " --> " << x << " --> " << x*m_Upsampling;
         m_ImageRegion.SetSize(0, x);
     }
     if (y!=m_ImageRegion.GetSize(1))
     {
         MITK_INFO << "Adjusting image height: " << m_ImageRegion.GetSize(1) << " --> " << y << " --> " << y*m_Upsampling;
         m_ImageRegion.SetSize(1, y);
     }
 
     // initialize k-space image
     m_KspaceImage = ItkDoubleImgType::New();
     m_KspaceImage->SetSpacing( m_Spacing );
     m_KspaceImage->SetOrigin( m_Origin );
     m_KspaceImage->SetDirection( m_DirectionMatrix );
     m_KspaceImage->SetLargestPossibleRegion( m_ImageRegion );
     m_KspaceImage->SetBufferedRegion( m_ImageRegion );
     m_KspaceImage->SetRequestedRegion( m_ImageRegion );
     m_KspaceImage->Allocate();
     m_KspaceImage->FillBuffer(0);
 
     // apply undersampling to image parameters
     m_UpsampledSpacing = m_Spacing;
     m_UpsampledImageRegion = m_ImageRegion;
     m_UpsampledSpacing[0] /= m_Upsampling;
     m_UpsampledSpacing[1] /= m_Upsampling;
     m_UpsampledImageRegion.SetSize(0, m_ImageRegion.GetSize()[0]*m_Upsampling);
     m_UpsampledImageRegion.SetSize(1, m_ImageRegion.GetSize()[1]*m_Upsampling);
 
     // everything from here on is using the upsampled image parameters!!!
     if (m_TissueMask.IsNull())
     {
         m_TissueMask = ItkUcharImgType::New();
         m_TissueMask->SetSpacing( m_UpsampledSpacing );
         m_TissueMask->SetOrigin( m_Origin );
         m_TissueMask->SetDirection( m_DirectionMatrix );
         m_TissueMask->SetLargestPossibleRegion( m_UpsampledImageRegion );
         m_TissueMask->SetBufferedRegion( m_UpsampledImageRegion );
         m_TissueMask->SetRequestedRegion( m_UpsampledImageRegion );
         m_TissueMask->Allocate();
         m_TissueMask->FillBuffer(1);
     }
 
     // resample frequency map
     if (m_FrequencyMap.IsNotNull())
     {
         itk::ResampleImageFilter<ItkDoubleImgType, ItkDoubleImgType>::Pointer resampler = itk::ResampleImageFilter<ItkDoubleImgType, ItkDoubleImgType>::New();
         resampler->SetInput(m_FrequencyMap);
         resampler->SetOutputParametersFromImage(m_FrequencyMap);
         resampler->SetSize(m_UpsampledImageRegion.GetSize());
         resampler->SetOutputSpacing(m_UpsampledSpacing);
         resampler->Update();
         m_FrequencyMap = resampler->GetOutput();
     }
 
     // resample fiber bundle for sufficient voxel coverage
     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];
     FiberBundleType fiberBundle = m_FiberBundle->GetDeepCopy();
     fiberBundle->ResampleFibers(minSpacing/m_VolumeAccuracy);
     double mmRadius = m_FiberRadius/1000;
     if (mmRadius>0)
         segmentVolume = M_PI*mmRadius*mmRadius*minSpacing/m_VolumeAccuracy;
 
     // generate double images to wokr with because we don't want to lose precision
     // we use a separate image for each compartment model
     std::vector< DoubleDwiType::Pointer > compartments;
     for (int i=0; i<m_FiberModels.size()+m_NonFiberModels.size(); i++)
     {
         DoubleDwiType::Pointer doubleDwi = DoubleDwiType::New();
         doubleDwi->SetSpacing( m_UpsampledSpacing );
         doubleDwi->SetOrigin( m_Origin );
         doubleDwi->SetDirection( m_DirectionMatrix );
         doubleDwi->SetLargestPossibleRegion( m_UpsampledImageRegion );
         doubleDwi->SetBufferedRegion( m_UpsampledImageRegion );
         doubleDwi->SetRequestedRegion( m_UpsampledImageRegion );
         doubleDwi->SetVectorLength( m_FiberModels[0]->GetNumGradients() );
         doubleDwi->Allocate();
         DoubleDwiType::PixelType pix;
         pix.SetSize(m_FiberModels[0]->GetNumGradients());
         pix.Fill(0.0);
         doubleDwi->FillBuffer(pix);
         compartments.push_back(doubleDwi);
     }
 
     double interpFact = 2*atan(-0.5*m_InterpolationShrink);
     double maxVolume = 0;
 
     vtkSmartPointer<vtkPolyData> fiberPolyData = fiberBundle->GetFiberPolyData();
     vtkSmartPointer<vtkCellArray> vLines = fiberPolyData->GetLines();
     vLines->InitTraversal();
 
     MITK_INFO << "Generating signal of " << m_FiberModels.size() << " fiber compartments";
     boost::progress_display disp(numFibers);
     for( int i=0; i<numFibers; i++ )
     {
         ++disp;
         vtkIdType   numPoints(0);
         vtkIdType*  points(NULL);
         vLines->GetNextCell ( numPoints, points );
         if (numPoints<2)
             continue;
 
         for( int j=0; j<numPoints; j++)
         {
             double* temp = fiberPolyData->GetPoint(points[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(fiberPolyData->GetPoint(points[j+1]))-v;
             else
                 dir = v-GetItkVector(fiberPolyData->GetPoint(points[j-1]));
 
             itk::Index<3> idx;
             itk::ContinuousIndex<float, 3> contIndex;
             m_TissueMask->TransformPhysicalPointToIndex(vertex, idx);
             m_TissueMask->TransformPhysicalPointToContinuousIndex(vertex, contIndex);
 
             double frac_x = contIndex[0] - idx[0];
             double frac_y = contIndex[1] - idx[1];
             double frac_z = contIndex[2] - idx[2];
             if (frac_x<0)
             {
                 idx[0] -= 1;
                 frac_x += 1;
             }
             if (frac_y<0)
             {
                 idx[1] -= 1;
                 frac_y += 1;
             }
             if (frac_z<0)
             {
                 idx[2] -= 1;
                 frac_z += 1;
             }
 
             frac_x = atan((0.5-frac_x)*m_InterpolationShrink)/interpFact + 0.5;
             frac_y = atan((0.5-frac_y)*m_InterpolationShrink)/interpFact + 0.5;
             frac_z = atan((0.5-frac_z)*m_InterpolationShrink)/interpFact + 0.5;
 
             // use trilinear interpolation
             itk::Index<3> newIdx;
             for (int x=0; x<2; x++)
             {
                 frac_x = 1-frac_x;
                 for (int y=0; y<2; y++)
                 {
                     frac_y = 1-frac_y;
                     for (int z=0; z<2; z++)
                     {
                         frac_z = 1-frac_z;
 
                         newIdx[0] = idx[0]+x;
                         newIdx[1] = idx[1]+y;
                         newIdx[2] = idx[2]+z;
 
                         double frac = frac_x*frac_y*frac_z;
 
                         // is position valid?
                         if (!m_TissueMask->GetLargestPossibleRegion().IsInside(newIdx) || m_TissueMask->GetPixel(newIdx)<=0)
                             continue;
 
                         // generate signal for each fiber compartment
                         for (int k=0; k<m_FiberModels.size(); k++)
                         {
                             DoubleDwiType::Pointer doubleDwi = compartments.at(k);
                             m_FiberModels[k]->SetFiberDirection(dir);
                             DoubleDwiType::PixelType pix = doubleDwi->GetPixel(newIdx);
                             pix += segmentVolume*frac*m_FiberModels[k]->SimulateMeasurement();
                             doubleDwi->SetPixel(newIdx, pix );
                             if (pix[baselineIndex]>maxVolume)
                                 maxVolume = pix[baselineIndex];
                         }
                     }
                 }
             }
         }
     }
 
     MITK_INFO << "Generating signal of " << m_NonFiberModels.size() << " non-fiber compartments";
     ImageRegionIterator<ItkUcharImgType> it3(m_TissueMask, m_TissueMask->GetLargestPossibleRegion());
     boost::progress_display disp3(m_TissueMask->GetLargestPossibleRegion().GetNumberOfPixels());
     double voxelVolume = m_UpsampledSpacing[0]*m_UpsampledSpacing[1]*m_UpsampledSpacing[2];
 
     double fact = 1;
     if (m_FiberRadius<0.0001)
         fact = voxelVolume/maxVolume;
 
     while(!it3.IsAtEnd())
     {
         ++disp3;
         DoubleDwiType::IndexType index = it3.GetIndex();
 
         if (it3.Get()>0)
         {
             // get fiber volume fraction
             DoubleDwiType::Pointer fiberDwi = compartments.at(0);
             DoubleDwiType::PixelType fiberPix = fiberDwi->GetPixel(index); // intra axonal compartment
             if (fact>1) // auto scale intra-axonal if no fiber radius is specified
             {
                 fiberPix *= fact;
                 fiberDwi->SetPixel(index, fiberPix);
             }
             double f = fiberPix[baselineIndex];
 
             if (f>voxelVolume || f>0 && m_EnforcePureFiberVoxels)  // more fiber than space in voxel?
             {
                 fiberDwi->SetPixel(index, fiberPix*voxelVolume/f);
 
                 for (int i=1; i<m_FiberModels.size(); i++)
                 {
                     DoubleDwiType::PixelType pix; pix.Fill(0.0);
                     compartments.at(i)->SetPixel(index, pix);
                 }
             }
             else
             {
                 double nonf = voxelVolume-f;    // non-fiber volume
                 double inter = 0;
                 if (m_FiberModels.size()>1)
                     inter = nonf * f;           // intra-axonal fraction of non fiber compartment scales linearly with f
                 double other = nonf - inter;    // rest of compartment
 
                 // adjust non-fiber and intra-axonal signal
                 for (int i=1; i<m_FiberModels.size(); i++)
                 {
                     DoubleDwiType::Pointer doubleDwi = compartments.at(i);
                     DoubleDwiType::PixelType pix = doubleDwi->GetPixel(index);
                     if (pix[baselineIndex]>0)
                         pix /= pix[baselineIndex];
                     pix *= inter;
                     doubleDwi->SetPixel(index, pix);
                 }
                 for (int i=0; i<m_NonFiberModels.size(); i++)
                 {
                     DoubleDwiType::Pointer doubleDwi = compartments.at(i+m_FiberModels.size());
                     DoubleDwiType::PixelType pix = doubleDwi->GetPixel(index) + m_NonFiberModels[i]->SimulateMeasurement()*other*m_NonFiberModels[i]->GetWeight();
                     doubleDwi->SetPixel(index, pix);
                 }
             }
         }
         ++it3;
     }
 
     // do k-space stuff
     MITK_INFO << "Adjusting complex signal";
     compartments = DoKspaceStuff(compartments);
 
     MITK_INFO << "Summing compartments and adding noise";
     unsigned int window = 0;
     unsigned int min = itk::NumericTraits<unsigned int>::max();
     ImageRegionIterator<DWIImageType> it4 (outImage, outImage->GetLargestPossibleRegion());
     DoubleDwiType::PixelType signal; signal.SetSize(m_FiberModels[0]->GetNumGradients());
     boost::progress_display disp4(outImage->GetLargestPossibleRegion().GetNumberOfPixels());
     while(!it4.IsAtEnd())
     {
         ++disp4;
         DWIImageType::IndexType index = it4.GetIndex();
         signal.Fill(0.0);
 
         // adjust fiber signal
         for (int i=0; i<m_FiberModels.size(); i++)
             signal += compartments.at(i)->GetPixel(index)*m_SignalScale;
 
         // adjust non-fiber signal
         for (int i=0; i<m_NonFiberModels.size(); i++)
             signal += compartments.at(m_FiberModels.size()+i)->GetPixel(index)*m_SignalScale;
 
         DoubleDwiType::PixelType accu = signal; accu.Fill(0.0);
         for (int i=0; i<m_NumberOfRepetitions; i++)
         {
             DoubleDwiType::PixelType temp = signal;
             m_NoiseModel->AddNoise(temp);
             accu += temp;
         }
         signal = accu/m_NumberOfRepetitions;
         for (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_FiberModels.at(0)->IsBaselineIndex(i) && signal[i]>window)
                 window = signal[i];
             if (!m_FiberModels.at(0)->IsBaselineIndex(i) && 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);
 }
 
 itk::Point<float, 3> TractsToDWIImageFilter::GetItkPoint(double point[3])
 {
     itk::Point<float, 3> itkPoint;
     itkPoint[0] = point[0];
     itkPoint[1] = point[1];
     itkPoint[2] = point[2];
     return itkPoint;
 }
 
 itk::Vector<double, 3> TractsToDWIImageFilter::GetItkVector(double point[3])
 {
     itk::Vector<double, 3> itkVector;
     itkVector[0] = point[0];
     itkVector[1] = point[1];
     itkVector[2] = point[2];
     return itkVector;
 }
 
 vnl_vector_fixed<double, 3> TractsToDWIImageFilter::GetVnlVector(double point[3])
 {
     vnl_vector_fixed<double, 3> vnlVector;
     vnlVector[0] = point[0];
     vnlVector[1] = point[1];
     vnlVector[2] = point[2];
     return vnlVector;
 }
 
 
 vnl_vector_fixed<double, 3> TractsToDWIImageFilter::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;
 }
 
 }
diff --git a/Plugins/org.mitk.gui.qt.diffusionimaging/documentation/UserManual/QmitkFiberfoxViewUserManual.dox b/Plugins/org.mitk.gui.qt.diffusionimaging/documentation/UserManual/QmitkFiberfoxViewUserManual.dox
index 22ba4ed943..0203830475 100644
--- a/Plugins/org.mitk.gui.qt.diffusionimaging/documentation/UserManual/QmitkFiberfoxViewUserManual.dox
+++ b/Plugins/org.mitk.gui.qt.diffusionimaging/documentation/UserManual/QmitkFiberfoxViewUserManual.dox
@@ -1,106 +1,108 @@
 /**
 \page org_mitk_views_fiberfoxview Fiberfox
 
 This view provides the user interface for Fiberfox [1], an interactive simulation tool for defining artificial white matter fibers and generating corresponding diffusion weighted images. Arbitrary fiber configurations like bent, crossing, kissing, twisting, and fanning bundles can be intuitively defined by positioning only a few 3D waypoints to trigger the automated generation of synthetic fibers. From these fibers a diffusion weighted signal is simulated using a flexible combination of various diffusion models. It can be modified using specified acquisition settings such as gradient direction, b-value, signal-to-noise ratio, image size, and resolution.
 
 <b>Available sections:</b>
   - \ref QmitkFiberfoxViewUserManualFiberDefinition
   - \ref QmitkFiberfoxViewUserManualSignalGeneration
   - \ref QmitkFiberfoxViewUserManualKnownIssues
   - \ref QmitkFiberfoxViewUserManualReferences
 \image html Fiberfox.png Fig. 1: Screenshot of the Fiberfox framework. The four render windows display an axial (top left), sagittal (top right) and coronal (bottom left) 2D cut as well as a 3D view of a synthetic fiber helix and the fiducials used to define its shape. In the 2D views the helix is superimposing the baseline volume of the corresponding diffusion weighted image. The sagittal render window shows a close-up view on one of the circular fiducials.
 
 \section QmitkFiberfoxViewUserManualFiberDefinition Fiber Definition
 
 Fiber strands are defined simply by placing markers in a 3D image volume. The fibers are then interpolated between these fiducials.
 
 
 <b>Example:</b>
 \li Chose an image volume to place the markers used to define the fiber pathway. If you don't have such an image available switch to the "Signal Generation" tab, define the size and spacing of the desired image and click "Generate Image". If no fiber bundle is selected, this will generate a dummy image that can be used to place the fiducials.
 \li Start placing fiducials at the desired positions to define the fiber pathway. To do that, click on the button with the circle pictogram, then click at the desired position and plane in the image volume and drag your mouse while keeping the button pressed to generate a circular shape. Adjust the shape using the control points (Fig. 2). The position of control point D introduces a twist of the fibers between two successive fiducials. The actual fiber generation is triggered automatically as soon as you place the second control point.
 \li In some cases the fibers are entangled in a way that can't be resolved by introducing an additional fiber twist. Fiberfox tries to avoid these situations, which arise from different normal orientations of succeeding fiducials, automatically. In rare cases this is not successful. Use the double-arrow button to flip the fiber positions of the selected fiducial in one dimension. Either the problem is resolved now or you can resolve it manually by adjusting the twist-control point.
 
 \image html Fiberfox-Fiducial.png Fig. 2: Control points defining the actual shape of the fiducial. A specifies the fiducials position in space, B and C the two ellipse radii and D the twisting angle between two successive fiducials.
 
 <b>Fiber Options:</b>
 \li <b>Real Time Fibers</b>: If checked, each parameter adjustment (fiducial position, number of fibers, ...) will be directly applied to the selected fiber bundle. If unchecked, the fibers will only be generated if the corresponding button "Generate Fibers" is clicked.
 \li <b>Advanced Options</b>: Show/hide advanced options
 \li <b>#Fibers</b>: Specifies the number of fibers that will be generated for the selected bundle.
 \li <b>Fiber Sampling</b>: Adjusts the number of points per cm that make up the fiber. A higher sampling rate is needed if high curvatures are modeled.
 \li <b>Tension, Continuity, Bias</b>: Parameters controlling the shape of the splines interpolation the fiducials. See <a href="http://en.wikipedia.org/wiki/Kochanek%E2%80%93Bartels_spline">Wikipedia</a> for details.
 
 
 <b>Fiducial Options:</b>
 \li <b>Use Constant Fiducial Radius</b>: If checked, all fiducials are treated as circles with the same radius. The first fiducial of the bundle defines the radius of all other fiducials.
 \li <b>Align with grid</b>: Click to shift all fiducial center points to the next voxel center.
 
 <b>Operations:</b>
 \li <b>Rotation</b>: Define the rotation of the selected fiber bundle around each axis (in degree).
 \li <b>Translation</b>: Define the translation of the selected fiber bundle along each axis (in mm).
 \li <b>Scaling</b>: Define a scaling factor for the selected fiber bundle in each dimension.
 \li <b>Transform Selection</b>: Apply specified rotation, translation and scaling to the selected Bundle/Fiducial
 \li <b>Copy Bundles</b>: Add copies of the selected fiber bundles to the datamanager.
 \li <b>Join Bundles</b>: Add new bundle to the datamanager that contains all fibers from the selected bundles.
 \li <b>Include Fiducials</b>: If checked, the specified transformation is also applied to the fiducials belonging to the selected fiber bundle and the fiducials are also copied.
 
 \image html FiberfoxExamples.png Fig. 3: Examples of artificial crossing (a,b), fanning (c,d), highly curved (e,f), kissing (g,h) and twisting (i,j) fibers as well as of the corresponding tensor images generated with Fiberfox.
 
 
 \section QmitkFiberfoxViewUserManualSignalGeneration Signal Generation
 
 To generate an artificial signal from the input fibers we follow the concepts recently presented by Panagiotaki et al. in a review and taxonomy of different compartment models [2]: a flexible model combining multiple compartments is used to simulate the anisotropic diffusion inside (intra-axonal compartment) and between axons (inter-axonal compartment), isotropic diffusion outside of the axons (extra-axonal compartment 1) and the restricted diffusion in other cell types (extra-axonal compartment 2) weighted according to their respective volume fraction.
 
 A diffusion weighted image is generated from the fibers by selecting the according fiber bundle in the datamanager and clicking "Generate Image". If some other diffusion weighted image is selected together with the fiber bundle, Fiberfox directly uses the parameters of the selected image (size, spacing, gradient directions, b-values) for the signal generation process. Additionally a binary image can be selected that defines the tissue area. Voxels outside of this mask will contain no signal, only noise.
 
 
 <b>Basic Image Settings:</b>
 \li <b>Image Dimensions</b>: Specifies actual image size (number of voxels in each dimension).
 \li <b>Image Spacing</b>: Specifies voxel size in mm. Beware that changing the voxel size also changes the signal strength, e.g. increasing the resolution from <em>2x2x2</em> mm to <em>1x1x1</em> mm decreases the signal obtained for each voxel by a factor 8.
 \li <b>Gradient Directions</b>: Number of gradients directions distributed equally over the half sphere. 10% baseline images are automatically added.
 \li <b>b-Value</b>: Diffusion weighting in s/mm². If an existing diffusion weighted image is used to set the basic parameters, the b-value is defined by the gradient direction magnitudes of this image, which also enables the use of multiple b-values.
 
 
 <b>Advanced Image Settings (activate checkbox "Advanced Options"):</b>
 \li <b>Repetitions</b>: Specifies the number of averages used for the acquisition to reduce noise.
 \li <b>Signal Scale</b>: Additional scaling factor for the signal in each voxel. The default value of 125 results in a maximum signal amplitude of 1000 for <em>2x2x2</em> mm voxels. Beware that changing this value without changing the noise variance results in a changed SNR. Adjustment of this value might be needed if the overall signal values are much too high or much too low (depends on a variety of factors like voxel size and relaxation times).
 \li <b>Echo Time <em>TE</em></b>: Time between the 90° excitation pulse and the first spin echo. Increasing this time results in a stronger <em>T2</em>-relaxation effect (<a href="http://en.wikipedia.org/wiki/Relaxation_%28NMR%29">Wikipedia</a>).
 \li <b>Line Readout Time</b>: Time to read one line in k-space. Increasing this time results in a stronger <em>T2*</em> effect which causes an attenuation of the higher frequencies in phase direction (here along y-axis) which again results in a blurring effect of sharp edges perpendicular to the phase direction.
 \li <b><em>T<sub>inhom</sub></em> Relaxation</b>: Time constant specifying the signal decay due to magnetic field inhomogeneities (also called <em>T2'</em>). Together with the tissue specific relaxation time constant <em>T2</em> this defines the <em>T2*</em> decay constant: <em>T2*=(T2 T2')/(T2+T2')</em>
 \li <b>Fiber Radius (in µm)</b>: Used to calculate the volume fractions of the used compartments (fiber, water, etc.). If set to 0 (default) the fiber radius is set automatically so that the voxel containing the most fibers is filled completely. A realistic axon radius ranges from about 5 to 20 microns. Using the automatic estimation the resulting value might very well be much larger or smaller than this range.
 \li <b>Interpolation Shrink</b>: The signal generated at each position along the fibers is distributed on the surrounding voxels using an interpolation scheme shaped like an arctangent function. Large values result in a steeper interpolation scheme approximating a nearest neighbor interpolation. Very small values result in an almost linear interpolation.
 \li <b>Enforce Pure Fiber Voxels</b>: If checked, the actual volume fractions of the single compartments are ignored. A voxel will either be filled by the intra axonal compartment completely or will contain no fiber at all.
 \li <b>Output k-Space Image</b>: Some of the effects simulated in our framework are modeled in the k-space representation of the actual image. Checking this box will output this frequency representation (amplitude spectrum).
 
 
 <b>Compartment Settings:</b>
 
 The group-boxes "Intra-axonal Compartment", "Inter-axonal Compartment" and "Extra-axonal Compartments" allow the specification which model to use and the corresponding model parameters. Currently the following models are implemented:
 \li <b>Stick</b>: The “stick” model describes diffusion in an idealized cylinder with zero radius. Parameter: Diffusivity <em>d</em>
 \li <b>Zeppelin</b>: Cylindrically symmetric diffusion tensor. Parameters: Parallel diffusivity <em>d<sub>||</sub></em> and perpendicular diffusivity  <em>d<sub>⊥</sub></em>
 \li <b>Tensor</b>: Full diffusion tensor. Parameters: Parallel diffusivity <em>d<sub>||</sub></em> and perpendicular diffusivity constants  <em>d<sub>⊥1</sub></em> and <em>d<sub>⊥2</sub></em>
 \li <b>Ball</b>: Isotropic compartment. Parameter: Diffusivity <em>d</em>
 \li <b>Astrosticks</b>: Consists of multiple stick models pointing in different directions. The single stick orientations can either be distributed equally over the sphere or are sampled randomly. The model represents signal coming from a type of glial cell called astrocytes, or populations of axons with arbitrary orientation. Parameters: randomization of the stick orientations and diffusivity of the sticks <em>d</em>.
 \li <b>Dot</b>: Isotropically restricted compartment. No parameter.
 
 For a detailed description of the single models, please refer to Panagiotaki <em>et al.</em> "Compartment models of the diffusion MR signal in brain white matter: A taxonomy and comparison."[2]. Additionally to the model parameters, each compartment has its own <em>T2</em> signal relaxation constant (in <em>ms</em>).
 
 
 <b>Noise and Artifacts:</b>
-\li <b>Variance</b>: Adds Rician noise with the specified variance to the signal.
-\li <b>Gibbs Ringing</b>: Ringing artifacts occurring on edges in the image due to the frequency low-pass filtering caused by the limited size of the k-space. The higher the oversampling factor, the larger the distance from the corresponding edge in which the ringing is still visible.
+\li <b>Rician Noise</b>: Add Rician noise with the specified variance to the signal.
+\li <b>N/2 Ghosts</b>: Specify the offset between successive lines in k-space. This offset causes ghost images in distance N/2 in phase direction due to the alternating EPI readout directions.
+\li <b>Distortions</b>: Simulate distortions due to magnetic field inhomogeneities. This is achieved by adding an additional phase during the readout process. The input is a frequency map specifying the inhomogeneities.
+\li <b>Gibbs Ringing</b>: Ringing artifacts occurring on edges in the image due to the frequency low-pass filtering caused by the limited size of the k-space. The higher the oversampling factor, the larger the distance from the corresponding edge in which the ringing is still visible. Keep in mind that increasing the oversampling factor results in a quadratic increase of computation time.
 
 \section QmitkFiberfoxViewUserManualKnownIssues Known Issues
 
 \li If fiducials are created in one of the marginal slices of the underlying image, a position change of the fiducial can be observed upon selection/deselection. If the fiducial is created in any other slice this bug does not occur.
 \li If a scaling factor is applied to the selcted fiber bundle, the corresponding fiducials are not scaled accordingly.
 \li In some cases the automatic update of the selected fiber bundle is not triggered even if "Real Time Fibers" is checked, e.g. if a fiducial is deleted. If this happens on can always force an update by pressing the "Generate Fibers" button.
 
 If any other issues or feature requests arises during the use of Fiberfox, please don't hesitate to send us an e-mail or directly report the issue in our bugtracker: http://bugs.mitk.org/
 
 \section QmitkFiberfoxViewUserManualReferences References
 
 [1] Peter F. Neher, Bram Stieltjes, Frederik B. Laun, Hans-Peter Meinzer, and Klaus H. Fritzsche: Fiberfox: A novel tool to generate software phantoms of complex fiber geometries. In proceedings: ISMRM 2013
 
 [2] Panagiotaki, E., Schneider, T., Siow, B., Hall, M.G., Lythgoe, M.F., Alexander, D.C.: Compartment models of the diffusion mr signal in brain white matter: A taxonomy and comparison. Neuroimage 59 (2012) 2241–2254
 
 */
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 1da5f2471a..10902ded2f 100644
--- a/Plugins/org.mitk.gui.qt.diffusionimaging/src/internal/QmitkFiberfoxView.cpp
+++ b/Plugins/org.mitk.gui.qt.diffusionimaging/src/internal/QmitkFiberfoxView.cpp
@@ -1,1661 +1,1670 @@
 /*===================================================================
 
 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 <mitkDiffusionImage.h>
 #include <mitkImageToItk.h>
 #include <itkDwiPhantomGenerationFilter.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 <mitkTensorModel.h>
 #include <mitkBallModel.h>
 #include <mitkStickModel.h>
 #include <mitkAstroStickModel.h>
 #include <mitkDotModel.h>
 #include <mitkRicianNoiseModel.h>
 #include <mitkGibbsRingingArtifact.h>
 #include <mitkSignalDecay.h>
 #include <itkScalableAffineTransform.h>
 #include <mitkLevelWindowProperty.h>
-#include <mitkNodePredicateProperty.h>
+#include <mitkNodePredicateOr.h>
+#include <mitkNodePredicateAnd.h>
+#include <mitkNodePredicateNot.h>
 
 #include <QMessageBox>
 
 #define _USE_MATH_DEFINES
 #include <math.h>
 
 const std::string QmitkFiberfoxView::VIEW_ID = "org.mitk.views.fiberfoxview";
 
 QmitkFiberfoxView::QmitkFiberfoxView()
     : QmitkAbstractView()
     , m_Controls( 0 )
     , m_SelectedImage( NULL )
 {
 
 }
 
 // Destructor
 QmitkFiberfoxView::~QmitkFiberfoxView()
 {
 
 }
 
 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 );
 
         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_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_GibbsRingingFrame->setVisible(false);
         m_Controls->m_NoiseFrame->setVisible(true);
         m_Controls->m_GhostFrame->setVisible(false);
         m_Controls->m_DistortionsFrame->setVisible(false);
 
         m_Controls->m_FrequencyMapBox->SetDataStorage(this->GetDataStorage());
         mitk::TNodePredicateDataType<mitk::Image>::Pointer isMitkImage = mitk::TNodePredicateDataType<mitk::Image>::New();
-        m_Controls->m_FrequencyMapBox->SetPredicate(isMitkImage);
+        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_FrequencyMapBox->SetPredicate(finalPredicate);
 
         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(int)), (QObject*) this, SLOT(OnFiberSamplingChanged(int)));
         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_AddGibbsRinging, SIGNAL(stateChanged(int)), (QObject*) this, SLOT(OnAddGibbsRinging(int)));
         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_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)));
     }
 }
 
 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);
 
     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;
     }
 }
 
 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);
 
     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;
     }
 }
 
 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_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;
     }
 }
 
 void QmitkFiberfoxView::OnConstantRadius(int value)
 {
     if (value>0 && m_Controls->m_RealTimeFibers->isChecked())
         GenerateFibers();
 }
 
 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::OnAddGibbsRinging(int value)
 {
     if (value>0)
         m_Controls->m_GibbsRingingFrame->setVisible(true);
     else
         m_Controls->m_GibbsRingingFrame->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 value)
 {
     if (m_Controls->m_RealTimeFibers->isChecked())
         GenerateFibers();
 }
 
 void QmitkFiberfoxView::OnFiberDensityChanged(int value)
 {
     if (m_Controls->m_RealTimeFibers->isChecked())
         GenerateFibers();
 }
 
 void QmitkFiberfoxView::OnFiberSamplingChanged(int value)
 {
     if (m_Controls->m_RealTimeFibers->isChecked())
         GenerateFibers();
 }
 
 void QmitkFiberfoxView::OnTensionChanged(double value)
 {
     if (m_Controls->m_RealTimeFibers->isChecked())
         GenerateFibers();
 }
 
 void QmitkFiberfoxView::OnContinuityChanged(double value)
 {
     if (m_Controls->m_RealTimeFibers->isChecked())
         GenerateFibers();
 }
 
 void QmitkFiberfoxView::OnBiasChanged(double value)
 {
     if (m_Controls->m_RealTimeFibers->isChecked())
         GenerateFibers();
 }
 
 void QmitkFiberfoxView::AlignOnGrid()
 {
     for (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::FiberBundleX*>(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::Geometry3D::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( 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::Geometry3D::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( 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::FiberBundleX*>(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::Geometry3D::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())
         return;
 
     mitk::DataStorage::SetOfObjects::ConstPointer children = GetDataStorage()->GetDerivations(m_SelectedImage);
 
     mitk::FiberBundleX::Pointer bundle = mitk::FiberBundleX::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);
 }
 
 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 );
 
 
     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);
     GetDataStorage()->Add(node, m_SelectedBundles.at(0));
 
     this->DisableCrosshairNavigation();
 
     mitk::PlanarFigureInteractor::Pointer figureInteractor = dynamic_cast<mitk::PlanarFigureInteractor*>(node->GetInteractor());
     if(figureInteractor.IsNull())
         figureInteractor = mitk::PlanarFigureInteractor::New("PlanarFigureInteractor", node);
     mitk::GlobalInteraction::GetInstance()->AddInteractor(figureInteractor);
 
     UpdateGui();
 }
 
 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::FiberBundleX*>((*it)->GetData()))
                 m_SelectedBundles.push_back(*it);
 
         if (m_SelectedBundles.empty())
             return;
     }
 
     vector< vector< mitk::PlanarEllipse::Pointer > > fiducials;
     vector< vector< unsigned int > > fliplist;
     for (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);
                     }
                     else
                     {
                         v.Normalize();
                         v *= radius;
                         ellipse->SetControlPoint(1, c+v);
                     }
                 }
                 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)
         {
             fiducials.push_back(fib);
             fliplist.push_back(flip);
         }
         else if (fib.size()>0)
             m_SelectedBundles.at(i)->SetData( mitk::FiberBundleX::New() );
 
         mitk::RenderingManager::GetInstance()->RequestUpdateAll();
     }
 
     itk::FibersFromPlanarFiguresFilter::Pointer filter = itk::FibersFromPlanarFiguresFilter::New();
     filter->SetFiducials(fiducials);
     filter->SetFlipList(fliplist);
 
     switch(m_Controls->m_DistributionBox->currentIndex()){
     case 0:
         filter->SetFiberDistribution(itk::FibersFromPlanarFiguresFilter::DISTRIBUTE_UNIFORM);
         break;
     case 1:
         filter->SetFiberDistribution(itk::FibersFromPlanarFiguresFilter::DISTRIBUTE_GAUSSIAN);
         filter->SetVariance(m_Controls->m_VarianceBox->value());
         break;
     }
 
     filter->SetDensity(m_Controls->m_FiberDensityBox->value());
     filter->SetTension(m_Controls->m_TensionBox->value());
     filter->SetContinuity(m_Controls->m_ContinuityBox->value());
     filter->SetBias(m_Controls->m_BiasBox->value());
     filter->SetFiberSampling(m_Controls->m_FiberSamplingBox->value());
     filter->Update();
     vector< mitk::FiberBundleX::Pointer > fiberBundles = filter->GetFiberBundles();
 
     for (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()
 {
     itk::ImageRegion<3> imageRegion;
     imageRegion.SetSize(0, m_Controls->m_SizeX->value());
     imageRegion.SetSize(1, m_Controls->m_SizeY->value());
     imageRegion.SetSize(2, m_Controls->m_SizeZ->value());
     mitk::Vector3D spacing;
     spacing[0] = m_Controls->m_SpacingX->value();
     spacing[1] = m_Controls->m_SpacingY->value();
     spacing[2] = m_Controls->m_SpacingZ->value();
 
     mitk::Point3D   origin;
     origin[0] = spacing[0]/2;
     origin[1] = spacing[1]/2;
     origin[2] = spacing[2]/2;
     itk::Matrix<double, 3, 3>           directionMatrix; directionMatrix.SetIdentity();
 
     if (m_SelectedBundles.empty())
     {
         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::Geometry3D* geom = image->GetGeometry();
         geom->SetOrigin(origin);
 
         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;
 
         mitk::BaseData::Pointer basedata = node->GetData();
         if (basedata.IsNotNull())
         {
             mitk::RenderingManager::GetInstance()->InitializeViews(
                         basedata->GetTimeSlicedGeometry(), mitk::RenderingManager::REQUEST_UPDATE_ALL, true );
             mitk::RenderingManager::GetInstance()->RequestUpdateAll();
         }
         UpdateGui();
 
         return;
     }
 
     if (m_SelectedImage.IsNotNull())
     {
         mitk::Image* img = dynamic_cast<mitk::Image*>(m_SelectedImage->GetData());
         itk::Image< float, 3 >::Pointer itkImg = itk::Image< float, 3 >::New();
         CastToItkImage< itk::Image< float, 3 > >(img, itkImg);
 
         imageRegion = itkImg->GetLargestPossibleRegion();
         spacing = itkImg->GetSpacing();
         origin = itkImg->GetOrigin();
         directionMatrix = itkImg->GetDirection();
     }
 
     DiffusionSignalModel<double>::GradientListType gradientList;
     double bVal = 1000;
     if (m_SelectedDWI.IsNull())
     {
         gradientList = GenerateHalfShell(m_Controls->m_NumGradientsBox->value());;
         bVal = m_Controls->m_BvalueBox->value();
     }
     else
     {
         mitk::DiffusionImage<short>::Pointer dwi = dynamic_cast<mitk::DiffusionImage<short>*>(m_SelectedDWI->GetData());
         imageRegion = dwi->GetVectorImage()->GetLargestPossibleRegion();
         spacing = dwi->GetVectorImage()->GetSpacing();
         origin = dwi->GetVectorImage()->GetOrigin();
         directionMatrix = dwi->GetVectorImage()->GetDirection();
         bVal = dwi->GetB_Value();
         mitk::DiffusionImage<short>::GradientDirectionContainerType::Pointer dirs = dwi->GetDirections();
         for (int i=0; i<dirs->Size(); i++)
         {
             DiffusionSignalModel<double>::GradientType g;
             g[0] = dirs->at(i)[0];
             g[1] = dirs->at(i)[1];
             g[2] = dirs->at(i)[2];
             gradientList.push_back(g);
         }
     }
 
 
     for (int i=0; i<m_SelectedBundles.size(); i++)
     {
         itk::TractsToDWIImageFilter::Pointer tractsToDwiFilter = itk::TractsToDWIImageFilter::New();
 
         // storage for generated phantom image
         mitk::DataNode::Pointer resultNode = mitk::DataNode::New();
         QString signalModelString("");
         itk::TractsToDWIImageFilter::DiffusionModelList fiberModelList, nonFiberModelList;
 
         // signal models
         double comp3Weight = 1;
         double comp4Weight = 0;
         if (m_Controls->m_Compartment4Box->currentIndex()>0)
         {
             comp4Weight = m_Controls->m_Comp4FractionBox->value();
             comp3Weight -= comp4Weight;
         }
 
         mitk::StickModel<double> stickModel1;
         mitk::StickModel<double> stickModel2;
         mitk::TensorModel<double> zeppelinModel1;
         mitk::TensorModel<double> zeppelinModel2;
         mitk::TensorModel<double> tensorModel1;
         mitk::TensorModel<double> tensorModel2;
         mitk::BallModel<double> ballModel1;
         mitk::BallModel<double> ballModel2;
         mitk::AstroStickModel<double> astrosticksModel1;
         mitk::AstroStickModel<double> astrosticksModel2;
         mitk::DotModel<double> dotModel1;
         mitk::DotModel<double> dotModel2;
 
         // compartment 1
         switch (m_Controls->m_Compartment1Box->currentIndex())
         {
         case 0:
             MITK_INFO << "Using stick model";
             stickModel1.SetGradientList(gradientList);
             stickModel1.SetDiffusivity(m_Controls->m_StickWidget1->GetD());
             stickModel1.SetT2(m_Controls->m_StickWidget1->GetT2());
             fiberModelList.push_back(&stickModel1);
             signalModelString += "Stick";
             resultNode->AddProperty("Fiberfox.Compartment1.Description", StringProperty::New("Intra-axonal compartment") );
             resultNode->AddProperty("Fiberfox.Compartment1.Model", StringProperty::New("Stick") );
             resultNode->AddProperty("Fiberfox.Compartment1.D", DoubleProperty::New(m_Controls->m_StickWidget1->GetD()) );
             resultNode->AddProperty("Fiberfox.Compartment1.T2", DoubleProperty::New(stickModel1.GetT2()) );
             break;
         case 1:
             MITK_INFO << "Using zeppelin model";
             zeppelinModel1.SetGradientList(gradientList);
             zeppelinModel1.SetBvalue(bVal);
             zeppelinModel1.SetDiffusivity1(m_Controls->m_ZeppelinWidget1->GetD1());
             zeppelinModel1.SetDiffusivity2(m_Controls->m_ZeppelinWidget1->GetD2());
             zeppelinModel1.SetDiffusivity3(m_Controls->m_ZeppelinWidget1->GetD2());
             zeppelinModel1.SetT2(m_Controls->m_ZeppelinWidget1->GetT2());
             fiberModelList.push_back(&zeppelinModel1);
             signalModelString += "Zeppelin";
             resultNode->AddProperty("Fiberfox.Compartment1.Description", StringProperty::New("Intra-axonal compartment") );
             resultNode->AddProperty("Fiberfox.Compartment1.Model", StringProperty::New("Zeppelin") );
             resultNode->AddProperty("Fiberfox.Compartment1.D1", DoubleProperty::New(m_Controls->m_ZeppelinWidget1->GetD1()) );
             resultNode->AddProperty("Fiberfox.Compartment1.D2", DoubleProperty::New(m_Controls->m_ZeppelinWidget1->GetD2()) );
             resultNode->AddProperty("Fiberfox.Compartment1.T2", DoubleProperty::New(zeppelinModel1.GetT2()) );
             break;
         case 2:
             MITK_INFO << "Using tensor model";
             tensorModel1.SetGradientList(gradientList);
             tensorModel1.SetBvalue(bVal);
             tensorModel1.SetDiffusivity1(m_Controls->m_TensorWidget1->GetD1());
             tensorModel1.SetDiffusivity2(m_Controls->m_TensorWidget1->GetD2());
             tensorModel1.SetDiffusivity3(m_Controls->m_TensorWidget1->GetD3());
             tensorModel1.SetT2(m_Controls->m_TensorWidget1->GetT2());
             fiberModelList.push_back(&tensorModel1);
             signalModelString += "Tensor";
             resultNode->AddProperty("Fiberfox.Compartment1.Description", StringProperty::New("Intra-axonal compartment") );
             resultNode->AddProperty("Fiberfox.Compartment1.Model", StringProperty::New("Tensor") );
             resultNode->AddProperty("Fiberfox.Compartment1.D1", DoubleProperty::New(m_Controls->m_TensorWidget1->GetD1()) );
             resultNode->AddProperty("Fiberfox.Compartment1.D2", DoubleProperty::New(m_Controls->m_TensorWidget1->GetD2()) );
             resultNode->AddProperty("Fiberfox.Compartment1.D3", DoubleProperty::New(m_Controls->m_TensorWidget1->GetD3()) );
             resultNode->AddProperty("Fiberfox.Compartment1.T2", DoubleProperty::New(zeppelinModel1.GetT2()) );
             break;
         }
 
         // compartment 2
         switch (m_Controls->m_Compartment2Box->currentIndex())
         {
         case 0:
             break;
         case 1:
             stickModel2.SetGradientList(gradientList);
             stickModel2.SetDiffusivity(m_Controls->m_StickWidget2->GetD());
             stickModel2.SetT2(m_Controls->m_StickWidget2->GetT2());
             fiberModelList.push_back(&stickModel2);
             signalModelString += "Stick";
             resultNode->AddProperty("Fiberfox.Compartment2.Description", StringProperty::New("Inter-axonal compartment") );
             resultNode->AddProperty("Fiberfox.Compartment2.Model", StringProperty::New("Stick") );
             resultNode->AddProperty("Fiberfox.Compartment2.D", DoubleProperty::New(m_Controls->m_StickWidget2->GetD()) );
             resultNode->AddProperty("Fiberfox.Compartment2.T2", DoubleProperty::New(stickModel2.GetT2()) );
             break;
         case 2:
             zeppelinModel2.SetGradientList(gradientList);
             zeppelinModel2.SetBvalue(bVal);
             zeppelinModel2.SetDiffusivity1(m_Controls->m_ZeppelinWidget2->GetD1());
             zeppelinModel2.SetDiffusivity2(m_Controls->m_ZeppelinWidget2->GetD2());
             zeppelinModel2.SetDiffusivity3(m_Controls->m_ZeppelinWidget2->GetD2());
             zeppelinModel2.SetT2(m_Controls->m_ZeppelinWidget2->GetT2());
             fiberModelList.push_back(&zeppelinModel2);
             signalModelString += "Zeppelin";
             resultNode->AddProperty("Fiberfox.Compartment2.Description", StringProperty::New("Inter-axonal compartment") );
             resultNode->AddProperty("Fiberfox.Compartment2.Model", StringProperty::New("Zeppelin") );
             resultNode->AddProperty("Fiberfox.Compartment2.D1", DoubleProperty::New(m_Controls->m_ZeppelinWidget2->GetD1()) );
             resultNode->AddProperty("Fiberfox.Compartment2.D2", DoubleProperty::New(m_Controls->m_ZeppelinWidget2->GetD2()) );
             resultNode->AddProperty("Fiberfox.Compartment2.T2", DoubleProperty::New(zeppelinModel2.GetT2()) );
             break;
         case 3:
             tensorModel2.SetGradientList(gradientList);
             tensorModel2.SetBvalue(bVal);
             tensorModel2.SetDiffusivity1(m_Controls->m_TensorWidget2->GetD1());
             tensorModel2.SetDiffusivity2(m_Controls->m_TensorWidget2->GetD2());
             tensorModel2.SetDiffusivity3(m_Controls->m_TensorWidget2->GetD3());
             tensorModel2.SetT2(m_Controls->m_TensorWidget2->GetT2());
             fiberModelList.push_back(&tensorModel2);
             signalModelString += "Tensor";
             resultNode->AddProperty("Fiberfox.Compartment2.Description", StringProperty::New("Inter-axonal compartment") );
             resultNode->AddProperty("Fiberfox.Compartment2.Model", StringProperty::New("Tensor") );
             resultNode->AddProperty("Fiberfox.Compartment2.D1", DoubleProperty::New(m_Controls->m_TensorWidget2->GetD1()) );
             resultNode->AddProperty("Fiberfox.Compartment2.D2", DoubleProperty::New(m_Controls->m_TensorWidget2->GetD2()) );
             resultNode->AddProperty("Fiberfox.Compartment2.D3", DoubleProperty::New(m_Controls->m_TensorWidget2->GetD3()) );
             resultNode->AddProperty("Fiberfox.Compartment2.T2", DoubleProperty::New(zeppelinModel2.GetT2()) );
             break;
         }
 
         // compartment 3
         switch (m_Controls->m_Compartment3Box->currentIndex())
         {
         case 0:
             ballModel1.SetGradientList(gradientList);
             ballModel1.SetBvalue(bVal);
             ballModel1.SetDiffusivity(m_Controls->m_BallWidget1->GetD());
             ballModel1.SetT2(m_Controls->m_BallWidget1->GetT2());
             ballModel1.SetWeight(comp3Weight);
             nonFiberModelList.push_back(&ballModel1);
             signalModelString += "Ball";
             resultNode->AddProperty("Fiberfox.Compartment3.Description", StringProperty::New("Extra-axonal compartment 1") );
             resultNode->AddProperty("Fiberfox.Compartment3.Model", StringProperty::New("Ball") );
             resultNode->AddProperty("Fiberfox.Compartment3.D", DoubleProperty::New(m_Controls->m_BallWidget1->GetD()) );
             resultNode->AddProperty("Fiberfox.Compartment3.T2", DoubleProperty::New(ballModel1.GetT2()) );
             break;
         case 1:
             astrosticksModel1.SetGradientList(gradientList);
             astrosticksModel1.SetBvalue(bVal);
             astrosticksModel1.SetDiffusivity(m_Controls->m_AstrosticksWidget1->GetD());
             astrosticksModel1.SetT2(m_Controls->m_AstrosticksWidget1->GetT2());
             astrosticksModel1.SetRandomizeSticks(m_Controls->m_AstrosticksWidget1->GetRandomizeSticks());
             astrosticksModel1.SetWeight(comp3Weight);
             nonFiberModelList.push_back(&astrosticksModel1);
             signalModelString += "Astrosticks";
             resultNode->AddProperty("Fiberfox.Compartment3.Description", StringProperty::New("Extra-axonal compartment 1") );
             resultNode->AddProperty("Fiberfox.Compartment3.Model", StringProperty::New("Astrosticks") );
             resultNode->AddProperty("Fiberfox.Compartment3.D", DoubleProperty::New(m_Controls->m_AstrosticksWidget1->GetD()) );
             resultNode->AddProperty("Fiberfox.Compartment3.T2", DoubleProperty::New(astrosticksModel1.GetT2()) );
             resultNode->AddProperty("Fiberfox.Compartment3.RandomSticks", BoolProperty::New(m_Controls->m_AstrosticksWidget1->GetRandomizeSticks()) );
             break;
         case 2:
             dotModel1.SetGradientList(gradientList);
             dotModel1.SetT2(m_Controls->m_DotWidget1->GetT2());
             dotModel1.SetWeight(comp3Weight);
             nonFiberModelList.push_back(&dotModel1);
             signalModelString += "Dot";
             resultNode->AddProperty("Fiberfox.Compartment3.Description", StringProperty::New("Extra-axonal compartment 1") );
             resultNode->AddProperty("Fiberfox.Compartment3.Model", StringProperty::New("Dot") );
             resultNode->AddProperty("Fiberfox.Compartment3.T2", DoubleProperty::New(dotModel1.GetT2()) );
             break;
         }
 
         // compartment 4
         switch (m_Controls->m_Compartment4Box->currentIndex())
         {
         case 0:
             break;
         case 1:
             ballModel2.SetGradientList(gradientList);
             ballModel2.SetBvalue(bVal);
             ballModel2.SetDiffusivity(m_Controls->m_BallWidget2->GetD());
             ballModel2.SetT2(m_Controls->m_BallWidget2->GetT2());
             ballModel2.SetWeight(comp4Weight);
             nonFiberModelList.push_back(&ballModel2);
             signalModelString += "Ball";
             resultNode->AddProperty("Fiberfox.Compartment4.Description", StringProperty::New("Extra-axonal compartment 2") );
             resultNode->AddProperty("Fiberfox.Compartment4.Model", StringProperty::New("Ball") );
             resultNode->AddProperty("Fiberfox.Compartment4.D", DoubleProperty::New(m_Controls->m_BallWidget2->GetD()) );
             resultNode->AddProperty("Fiberfox.Compartment4.T2", DoubleProperty::New(ballModel2.GetT2()) );
             break;
         case 2:
             astrosticksModel2.SetGradientList(gradientList);
             astrosticksModel2.SetBvalue(bVal);
             astrosticksModel2.SetDiffusivity(m_Controls->m_AstrosticksWidget2->GetD());
             astrosticksModel2.SetT2(m_Controls->m_AstrosticksWidget2->GetT2());
             astrosticksModel2.SetRandomizeSticks(m_Controls->m_AstrosticksWidget2->GetRandomizeSticks());
             astrosticksModel2.SetWeight(comp4Weight);
             nonFiberModelList.push_back(&astrosticksModel2);
             signalModelString += "Astrosticks";
             resultNode->AddProperty("Fiberfox.Compartment4.Description", StringProperty::New("Extra-axonal compartment 2") );
             resultNode->AddProperty("Fiberfox.Compartment4.Model", StringProperty::New("Astrosticks") );
             resultNode->AddProperty("Fiberfox.Compartment4.D", DoubleProperty::New(m_Controls->m_AstrosticksWidget2->GetD()) );
             resultNode->AddProperty("Fiberfox.Compartment4.T2", DoubleProperty::New(astrosticksModel2.GetT2()) );
             resultNode->AddProperty("Fiberfox.Compartment4.RandomSticks", BoolProperty::New(m_Controls->m_AstrosticksWidget2->GetRandomizeSticks()) );
             break;
         case 3:
             dotModel2.SetGradientList(gradientList);
             dotModel2.SetT2(m_Controls->m_DotWidget2->GetT2());
             dotModel2.SetWeight(comp4Weight);
             nonFiberModelList.push_back(&dotModel2);
             signalModelString += "Dot";
             resultNode->AddProperty("Fiberfox.Compartment4.Description", StringProperty::New("Extra-axonal compartment 2") );
             resultNode->AddProperty("Fiberfox.Compartment4.Model", StringProperty::New("Dot") );
             resultNode->AddProperty("Fiberfox.Compartment4.T2", DoubleProperty::New(dotModel2.GetT2()) );
             break;
         }
 
         itk::TractsToDWIImageFilter::KspaceArtifactList artifactList;
 
         // artifact models
         QString artifactModelString("");
         double noiseVariance = 0;
         if (m_Controls->m_AddNoise->isChecked())
         {
             noiseVariance = m_Controls->m_NoiseLevel->value();
             artifactModelString += "_NOISE";
             artifactModelString += QString::number(noiseVariance);
             resultNode->AddProperty("Fiberfox.Noise-Variance", DoubleProperty::New(noiseVariance));
         }
         mitk::RicianNoiseModel<double> noiseModel;
         noiseModel.SetNoiseVariance(noiseVariance);
 
         mitk::GibbsRingingArtifact<double> gibbsModel;
         if (m_Controls->m_AddGibbsRinging->isChecked())
         {
             artifactModelString += "_RINGING";
             resultNode->AddProperty("Fiberfox.k-Space-Undersampling", IntProperty::New(m_Controls->m_KspaceUndersamplingBox->currentText().toInt()));
             gibbsModel.SetKspaceCropping((double)m_Controls->m_KspaceUndersamplingBox->currentText().toInt());
             artifactList.push_back(&gibbsModel);
         }
 
         if ( this->m_Controls->m_TEbox->value() < imageRegion.GetSize(1)*m_Controls->m_LineReadoutTimeBox->value() )
         {
             this->m_Controls->m_TEbox->setValue( imageRegion.GetSize(1)*m_Controls->m_LineReadoutTimeBox->value() );
             QMessageBox::information( NULL, "Warning", "Echo time is too short! Time not sufficient to read slice. Automaticall adjusted to "+QString::number(this->m_Controls->m_TEbox->value())+" ms");
         }
 
         double lineReadoutTime = m_Controls->m_LineReadoutTimeBox->value();
 
         // adjusting line readout time to the adapted image size needed for the DFT
         int y = imageRegion.GetSize(1);
         if ( y%2 == 1 )
             y += 1;
         if ( y>imageRegion.GetSize(1) )
             lineReadoutTime *= (double)imageRegion.GetSize(1)/y;
 
         // add signal contrast model
         mitk::SignalDecay<double> contrastModel;
         contrastModel.SetTinhom(this->m_Controls->m_T2starBox->value());
         contrastModel.SetTE(this->m_Controls->m_TEbox->value());
         contrastModel.SetTline(lineReadoutTime);
         artifactList.push_back(&contrastModel);
 
         // add N/2 ghosting
         double kOffset = 0;
         if (m_Controls->m_AddGhosts->isChecked())
         {
             artifactModelString += "_GHOST";
             kOffset = m_Controls->m_kOffsetBox->value();
             resultNode->AddProperty("Fiberfox.Line-Offset", DoubleProperty::New(kOffset));
         }
 
         // add distortions
         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 (imageRegion.GetSize(0)==itkImg->GetLargestPossibleRegion().GetSize(0) &&
                 imageRegion.GetSize(1)==itkImg->GetLargestPossibleRegion().GetSize(1) &&
                 imageRegion.GetSize(2)==itkImg->GetLargestPossibleRegion().GetSize(2))
                 tractsToDwiFilter->SetFrequencyMap(itkImg);
         }
 
         mitk::FiberBundleX::Pointer fiberBundle = dynamic_cast<mitk::FiberBundleX*>(m_SelectedBundles.at(i)->GetData());
         if (fiberBundle->GetNumFibers()<=0)
             continue;
 
         tractsToDwiFilter->SetImageRegion(imageRegion);
         tractsToDwiFilter->SetSpacing(spacing);
         tractsToDwiFilter->SetOrigin(origin);
         tractsToDwiFilter->SetDirectionMatrix(directionMatrix);
         tractsToDwiFilter->SetFiberBundle(fiberBundle);
         tractsToDwiFilter->SetFiberModels(fiberModelList);
         tractsToDwiFilter->SetNonFiberModels(nonFiberModelList);
         tractsToDwiFilter->SetNoiseModel(&noiseModel);
         tractsToDwiFilter->SetKspaceArtifacts(artifactList);
         tractsToDwiFilter->SetkOffset(kOffset);
         tractsToDwiFilter->SettLine(m_Controls->m_LineReadoutTimeBox->value());
         tractsToDwiFilter->SetNumberOfRepetitions(m_Controls->m_RepetitionsBox->value());
         tractsToDwiFilter->SetEnforcePureFiberVoxels(m_Controls->m_EnforcePureFiberVoxelsBox->isChecked());
         tractsToDwiFilter->SetInterpolationShrink(m_Controls->m_InterpolationShrink->value());
         tractsToDwiFilter->SetFiberRadius(m_Controls->m_FiberRadius->value());
         tractsToDwiFilter->SetSignalScale(m_Controls->m_SignalScaleBox->value());
 
         if (m_TissueMask.IsNotNull())
         {
             ItkUcharImgType::Pointer mask = ItkUcharImgType::New();
             mitk::CastToItkImage<ItkUcharImgType>(m_TissueMask, mask);
             tractsToDwiFilter->SetTissueMask(mask);
         }
         tractsToDwiFilter->Update();
 
         mitk::DiffusionImage<short>::Pointer image = mitk::DiffusionImage<short>::New();
         image->SetVectorImage( tractsToDwiFilter->GetOutput() );
         image->SetB_Value(bVal);
         image->SetDirections(gradientList);
         image->InitializeFromVectorImage();
         resultNode->SetData( image );
         resultNode->SetName(m_SelectedBundles.at(i)->GetName()
                             +"_D"+QString::number(imageRegion.GetSize(0)).toStdString()
                             +"-"+QString::number(imageRegion.GetSize(1)).toStdString()
                             +"-"+QString::number(imageRegion.GetSize(2)).toStdString()
                             +"_S"+QString::number(spacing[0]).toStdString()
                             +"-"+QString::number(spacing[1]).toStdString()
                             +"-"+QString::number(spacing[2]).toStdString()
                             +"_b"+QString::number(bVal).toStdString()
                             +"_"+signalModelString.toStdString()
                             +artifactModelString.toStdString());
         GetDataStorage()->Add(resultNode, m_SelectedBundles.at(i));
 
         resultNode->AddProperty("Fiberfox.InterpolationShrink", IntProperty::New(m_Controls->m_InterpolationShrink->value()));
         resultNode->AddProperty("Fiberfox.SignalScale", IntProperty::New(m_Controls->m_SignalScaleBox->value()));
         resultNode->AddProperty("Fiberfox.FiberRadius", IntProperty::New(m_Controls->m_FiberRadius->value()));
         resultNode->AddProperty("Fiberfox.Tinhom", IntProperty::New(m_Controls->m_T2starBox->value()));
         resultNode->AddProperty("Fiberfox.Repetitions", IntProperty::New(m_Controls->m_RepetitionsBox->value()));
         resultNode->AddProperty("Fiberfox.b-value", DoubleProperty::New(bVal));
         resultNode->AddProperty("Fiberfox.Model", StringProperty::New(signalModelString.toStdString()));
         resultNode->AddProperty("Fiberfox.PureFiberVoxels", BoolProperty::New(m_Controls->m_EnforcePureFiberVoxelsBox->isChecked()));
         resultNode->AddProperty("binary", BoolProperty::New(false));
         resultNode->SetProperty( "levelwindow", mitk::LevelWindowProperty::New(tractsToDwiFilter->GetLevelWindow()) );
 
         if (m_Controls->m_KspaceImageBox->isChecked())
         {
             itk::Image<double, 3>::Pointer kspace = tractsToDwiFilter->GetKspaceImage();
             mitk::Image::Pointer image = mitk::Image::New();
             image->InitializeByItk(kspace.GetPointer());
             image->SetVolume(kspace->GetBufferPointer());
 
             mitk::DataNode::Pointer node = mitk::DataNode::New();
             node->SetData( image );
             node->SetName(m_SelectedBundles.at(i)->GetName()+"_k-space");
             GetDataStorage()->Add(node, m_SelectedBundles.at(i));
         }
 
         mitk::BaseData::Pointer basedata = resultNode->GetData();
         if (basedata.IsNotNull())
         {
             mitk::RenderingManager::GetInstance()->InitializeViews(
                         basedata->GetTimeSlicedGeometry(), mitk::RenderingManager::REQUEST_UPDATE_ALL, true );
             mitk::RenderingManager::GetInstance()->RequestUpdateAll();
         }
     }
 }
 
 void QmitkFiberfoxView::ApplyTransform()
 {
     vector< mitk::DataNode::Pointer > selectedBundles;
     for( 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::FiberBundleX*>(fibNode->GetData()) )
                 selectedBundles.push_back(fibNode);
         }
     }
     if (selectedBundles.empty())
         selectedBundles = m_SelectedBundles2;
 
     if (!selectedBundles.empty())
     {
         std::vector<mitk::DataNode::Pointer>::const_iterator it = selectedBundles.begin();
         for (it; it!=selectedBundles.end(); ++it)
         {
             mitk::FiberBundleX::Pointer fib = dynamic_cast<mitk::FiberBundleX*>((*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::Geometry3D* 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< float, 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< float, 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< float, 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< float, 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);
                     }
                 }
             }
         }
     }
     else
     {
         for (int i=0; i<m_SelectedFiducials.size(); i++)
         {
             mitk::PlanarEllipse* pe = dynamic_cast<mitk::PlanarEllipse*>(m_SelectedFiducials.at(i)->GetData());
             mitk::Geometry3D* 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< float, 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< float, 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< float, 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< float, 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());
         }
         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("QmitkFiberProcessingView") << "Select at least one fiber bundle!";
         return;
     }
 
     std::vector<mitk::DataNode::Pointer>::const_iterator it = m_SelectedBundles.begin();
     for (it; 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::FiberBundleX::Pointer fib = dynamic_cast<mitk::FiberBundleX*>((*it)->GetData());
         mitk::FiberBundleX::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 = mitk::PlanarEllipse::New();
                     pe->DeepCopy(dynamic_cast<mitk::PlanarEllipse*>(fiducialNode->GetData()));
                     mitk::DataNode::Pointer newNode = mitk::DataNode::New();
                     newNode->SetData(pe);
                     newNode->SetName(fiducialNode->GetName());
                     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("QmitkFiberProcessingView") << "Select at least two fiber bundles!";
         return;
     }
 
     std::vector<mitk::DataNode::Pointer>::const_iterator it = m_SelectedBundles.begin();
     mitk::FiberBundleX::Pointer newBundle = dynamic_cast<mitk::FiberBundleX*>((*it)->GetData());
     QString name("");
     name += QString((*it)->GetName().c_str());
     ++it;
     for (it; it!=m_SelectedBundles.end(); ++it)
     {
         newBundle = newBundle->AddBundle(dynamic_cast<mitk::FiberBundleX*>((*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_FiberBundleLabel->setText("<font color='red'>mandatory</font>");
     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);
 
     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())
     {
         m_Controls->m_TransformBundlesButton->setEnabled(true);
         m_Controls->m_CircleButton->setEnabled(true);
         m_Controls->m_FiberGenMessage->setVisible(false);
         m_Controls->m_AlignOnGrid->setEnabled(true);
     }
 
     if (m_TissueMask.IsNotNull() || m_SelectedImage.IsNotNull())
     {
         m_Controls->m_GeometryMessage->setVisible(true);
         m_Controls->m_GeometryFrame->setEnabled(false);
     }
 
     if (m_SelectedDWI.IsNotNull())
     {
         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);
     }
 
     if (!m_SelectedBundles.empty())
     {
         m_Controls->m_CopyBundlesButton->setEnabled(true);
         m_Controls->m_GenerateFibersButton->setEnabled(true);
         m_Controls->m_FiberBundleLabel->setText(m_SelectedBundles.at(0)->GetName().c_str());
 
         if (m_SelectedBundles.size()>1)
             m_Controls->m_JoinBundlesButton->setEnabled(true);
     }
 }
 
 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_TissueMask = NULL;
     m_SelectedBundles.clear();
     m_SelectedImage = NULL;
     m_SelectedDWI = NULL;
     m_Controls->m_TissueMaskLabel->setText("<font color='grey'>optional</font>");
 
     // iterate all selected objects, adjust warning visibility
     for( int i=0; i<nodes.size(); i++)
     {
         mitk::DataNode::Pointer node = nodes.at(i);
 
         if ( node.IsNotNull() && dynamic_cast<mitk::DiffusionImage<short>*>(node->GetData()) )
         {
             m_SelectedDWI = node;
             m_SelectedImage = node;
             m_SelectedImages.push_back(node);
         }
         else if( node.IsNotNull() && dynamic_cast<mitk::Image*>(node->GetData()) )
         {
             m_SelectedImages.push_back(node);
             m_SelectedImage = node;
             bool isBinary = false;
             node->GetPropertyValue<bool>("binary", isBinary);
             if (isBinary)
             {
                 m_TissueMask = dynamic_cast<mitk::Image*>(node->GetData());
                 m_Controls->m_TissueMaskLabel->setText(node->GetName().c_str());
             }
         }
         else if ( node.IsNotNull() && dynamic_cast<mitk::FiberBundleX*>(node->GetData()) )
         {
             m_SelectedBundles2.push_back(node);
             if (m_Controls->m_RealTimeFibers->isChecked())
             {
                 m_SelectedBundles.push_back(node);
                 mitk::FiberBundleX::Pointer newFib = dynamic_cast<mitk::FiberBundleX*>(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::FiberBundleX*>(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( 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->GetInteractor());
 
         mitk::DataNode* nonConstNode = const_cast<mitk::DataNode*>( node );
         if(figureInteractor.IsNull())
         {
             figureInteractor = mitk::PlanarFigureInteractor::New("PlanarFigureInteractor", nonConstNode);
         }
         else
         {
             // just to be sure that the interactor is not added twice
             mitk::GlobalInteraction::GetInstance()->RemoveInteractor(figureInteractor);
         }
 
         MITK_DEBUG << "adding interactor to globalinteraction";
         mitk::GlobalInteraction::GetInstance()->AddInteractor(figureInteractor);
 
         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();
 }
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 e5196ee11d..6daeb16abe 100644
--- a/Plugins/org.mitk.gui.qt.diffusionimaging/src/internal/QmitkFiberfoxViewControls.ui
+++ b/Plugins/org.mitk.gui.qt.diffusionimaging/src/internal/QmitkFiberfoxViewControls.ui
@@ -1,2130 +1,2140 @@
 <?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>493</width>
     <height>1482</height>
    </rect>
   </property>
   <property name="windowTitle">
    <string>Form</string>
   </property>
   <layout class="QGridLayout" name="gridLayout_2">
    <item row="0" column="0">
     <widget class="QTabWidget" name="tabWidget">
      <property name="currentIndex">
-      <number>1</number>
+      <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>
            </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="4" column="0">
            <widget class="QCommandLinkButton" name="m_CopyBundlesButton">
             <property name="enabled">
              <bool>false</bool>
             </property>
             <property name="text">
              <string>Copy Bundles</string>
             </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>
            </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="margin">
               <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="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="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="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="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="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="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="5" column="0">
            <widget class="QCommandLinkButton" name="m_JoinBundlesButton">
             <property name="enabled">
              <bool>false</bool>
             </property>
             <property name="text">
              <string>Join Bundles</string>
             </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="margin">
               <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="margin">
                  <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="0" column="1">
                  <widget class="QSpinBox" name="m_FiberSamplingBox">
                   <property name="toolTip">
                    <string>Fiber sampling points (per cm)</string>
                   </property>
                   <property name="minimum">
                    <number>1</number>
                   </property>
                   <property name="maximum">
                    <number>100</number>
                   </property>
                   <property name="singleStep">
                    <number>1</number>
                   </property>
                   <property name="value">
                    <number>10</number>
                   </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>
                </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="margin">
                  <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>
            </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="margin">
               <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="margin">
               <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="margin">
            <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="5" 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="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>
            </widget>
           </item>
           <item row="1" column="0">
            <widget class="QmitkStickModelParametersWidget" name="m_StickWidget1" native="true"/>
           </item>
           <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>
          </layout>
         </widget>
        </item>
        <item row="0" column="0">
         <widget class="QGroupBox" name="groupBox_2">
          <property name="title">
           <string>Data</string>
          </property>
          <layout class="QGridLayout" name="gridLayout_10">
           <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="0" column="2" rowspan="2">
            <widget class="QLabel" name="m_FiberBundleLabel">
             <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="3" column="0" colspan="2">
            <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="3" column="2">
            <widget class="QLabel" name="m_TissueMaskLabel">
             <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>
          </layout>
         </widget>
        </item>
        <item row="7" 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="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>
            </widget>
           </item>
           <item row="8" column="0">
            <widget class="QmitkAstrosticksModelParametersWidget" name="m_AstrosticksWidget1" native="true"/>
           </item>
           <item row="14" column="0">
            <widget class="QmitkAstrosticksModelParametersWidget" name="m_AstrosticksWidget2" native="true"/>
           </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="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>
            </widget>
           </item>
           <item row="11" column="0">
            <widget class="Line" name="line_2">
             <property name="orientation">
              <enum>Qt::Horizontal</enum>
             </property>
            </widget>
           </item>
           <item row="15" column="0">
            <widget class="QmitkDotModelParametersWidget" name="m_DotWidget2" native="true"/>
           </item>
           <item row="16" 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="margin">
               <number>0</number>
              </property>
              <item row="0" column="1">
               <widget class="QDoubleSpinBox" name="m_Comp4FractionBox">
                <property name="toolTip">
                 <string>Weighting factor between the two extra-axonal compartments.</string>
                </property>
                <property name="maximum">
                 <double>1.000000000000000</double>
                </property>
                <property name="singleStep">
                 <double>0.100000000000000</double>
                </property>
                <property name="value">
                 <double>0.300000000000000</double>
                </property>
               </widget>
              </item>
              <item row="0" column="0">
               <widget class="QLabel" name="m_NoiseLabel_3">
                <property name="text">
                 <string>Compartment Fraction:</string>
                </property>
               </widget>
              </item>
             </layout>
            </widget>
           </item>
           <item row="9" column="0">
            <widget class="QmitkDotModelParametersWidget" name="m_DotWidget1" native="true"/>
           </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>Start DWI generation from selected fiebr bundle. If no fiber bundle is selected, a grayscale image containing a simple gradient is generated.</string>
          </property>
          <property name="text">
           <string>Generate Image</string>
          </property>
         </widget>
        </item>
        <item row="4" column="0">
         <widget class="QGroupBox" name="groupBox">
          <property name="title">
           <string>Image Settings</string>
          </property>
          <layout class="QGridLayout" name="gridLayout">
           <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="margin">
               <number>0</number>
              </property>
              <property name="horizontalSpacing">
               <number>6</number>
              </property>
              <item row="4" 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="8" column="0">
               <widget class="QCheckBox" name="m_KspaceImageBox">
                <property name="text">
                 <string>Output k-Space Image</string>
                </property>
                <property name="checked">
                 <bool>false</bool>
                </property>
               </widget>
              </item>
              <item row="6" column="1">
               <widget class="QSpinBox" name="m_InterpolationShrink">
                <property name="toolTip">
                 <string>Large values shrink (towards nearest neighbour interpolation), small values strech interpolation function (towards linear interpolation).</string>
                </property>
                <property name="minimum">
                 <number>1</number>
                </property>
                <property name="maximum">
                 <number>10000</number>
                </property>
                <property name="value">
                 <number>10</number>
                </property>
               </widget>
              </item>
              <item row="3" 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="7" column="0">
               <widget class="QCheckBox" name="m_EnforcePureFiberVoxelsBox">
                <property name="toolTip">
                 <string>Treat voxel content as fiber-only if at least one fiber is present.</string>
                </property>
                <property name="text">
                 <string>Enforce Pure Fiber Voxels</string>
                </property>
                <property name="checked">
                 <bool>false</bool>
                </property>
               </widget>
              </item>
              <item row="2" 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="5" column="0">
               <widget class="QLabel" name="m_TensorsToDWINumDirsLabel_4">
                <property name="text">
                 <string>Fiber Radius:</string>
                </property>
               </widget>
              </item>
              <item row="6" column="0">
               <widget class="QLabel" name="m_TensorsToDWINumDirsLabel_3">
                <property name="text">
                 <string>Interpolation Shrink:</string>
                </property>
               </widget>
              </item>
              <item row="0" column="0">
               <widget class="QLabel" name="m_TensorsToDWINumDirsLabel_2">
                <property name="text">
                 <string>Repetitions:</string>
                </property>
               </widget>
              </item>
              <item row="2" 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="3" 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="0" column="1">
               <widget class="QSpinBox" name="m_RepetitionsBox">
                <property name="toolTip">
                 <string>Number of signal averages. Increase to reduce noise.</string>
                </property>
                <property name="minimum">
                 <number>1</number>
                </property>
                <property name="maximum">
                 <number>100</number>
                </property>
                <property name="singleStep">
                 <number>1</number>
                </property>
                <property name="value">
                 <number>1</number>
                </property>
               </widget>
              </item>
              <item row="4" 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="5" 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="1" column="0">
               <widget class="QLabel" name="m_TensorsToDWINumDirsLabel_5">
                <property name="text">
                 <string>Signal Scale:</string>
                </property>
               </widget>
              </item>
              <item row="1" 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>125</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="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="margin">
               <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>
           <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="margin">
               <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>b-Value:</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 mm/s²</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="6" column="0">
            <widget class="QCheckBox" name="m_AdvancedOptionsBox_2">
             <property name="text">
              <string>Advanced Options</string>
             </property>
            </widget>
           </item>
          </layout>
         </widget>
        </item>
        <item row="10" 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="9" column="0">
         <widget class="QGroupBox" name="groupBox_3">
          <property name="title">
           <string>Noise and Artifacts</string>
          </property>
          <layout class="QGridLayout" name="gridLayout_6">
           <item row="8" column="0">
            <widget class="QFrame" name="m_GibbsRingingFrame">
             <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_4">
              <property name="horizontalSpacing">
               <number>6</number>
              </property>
              <property name="margin">
               <number>0</number>
              </property>
              <item row="0" column="0">
               <widget class="QLabel" name="m_TensorsToDWIBValueLabel_14">
                <property name="toolTip">
                 <string/>
                </property>
                <property name="statusTip">
                 <string/>
                </property>
                <property name="whatsThis">
                 <string/>
                </property>
                <property name="text">
                 <string>k-Space Undersampling:</string>
                </property>
                <property name="wordWrap">
                 <bool>false</bool>
                </property>
               </widget>
              </item>
              <item row="0" column="1">
               <widget class="QComboBox" name="m_KspaceUndersamplingBox">
                <property name="toolTip">
                 <string>Image is upsampled using this factor, afterwards fourier transformed, cropped to the original size and then inverse fourier transformed.</string>
                </property>
                <property name="currentIndex">
                 <number>0</number>
                </property>
                <item>
                 <property name="text">
                  <string>2</string>
                 </property>
                </item>
                <item>
                 <property name="text">
                  <string>4</string>
                 </property>
                </item>
                <item>
                 <property name="text">
                  <string>8</string>
                 </property>
                </item>
                <item>
                 <property name="text">
                  <string>16</string>
                 </property>
                </item>
                <item>
                 <property name="text">
                  <string>32</string>
                 </property>
                </item>
                <item>
                 <property name="text">
                  <string>64</string>
                 </property>
                </item>
                <item>
                 <property name="text">
                  <string>128</string>
                 </property>
                </item>
                <item>
                 <property name="text">
                  <string>256</string>
                 </property>
                </item>
               </widget>
              </item>
             </layout>
            </widget>
           </item>
           <item row="5" 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="7" column="0">
            <widget class="QCheckBox" name="m_AddGibbsRinging">
             <property name="text">
              <string>Add Gibbs Ringing</string>
             </property>
             <property name="checked">
              <bool>false</bool>
             </property>
            </widget>
           </item>
           <item row="0" column="0">
            <widget class="QCheckBox" name="m_AddNoise">
             <property name="text">
              <string>Add Rician Noise</string>
             </property>
             <property name="checked">
              <bool>true</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="margin">
               <number>0</number>
              </property>
              <item row="0" column="0">
               <widget class="QLabel" name="m_NoiseLabel">
                <property name="text">
                 <string>Variance:</string>
                </property>
               </widget>
              </item>
              <item row="0" column="1">
               <widget class="QDoubleSpinBox" name="m_NoiseLevel">
                <property name="toolTip">
                 <string>Variance of Rician noise model.</string>
                </property>
                <property name="decimals">
                 <number>4</number>
                </property>
                <property name="minimum">
                 <double>0.000000000000000</double>
                </property>
                <property name="maximum">
                 <double>100000.000000000000000</double>
                </property>
                <property name="singleStep">
                 <double>0.001000000000000</double>
                </property>
                <property name="value">
                 <double>25.000000000000000</double>
                </property>
               </widget>
              </item>
             </layout>
            </widget>
           </item>
           <item row="3" column="0">
            <widget class="QCheckBox" name="m_AddGhosts">
             <property name="text">
-             <string>Add N/Ghosts</string>
+             <string>Add N/2 Ghosts</string>
             </property>
             <property name="checked">
              <bool>false</bool>
             </property>
            </widget>
           </item>
           <item row="4" 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="margin">
               <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/>
+                <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>0.100000000000000</double>
                </property>
               </widget>
              </item>
             </layout>
            </widget>
           </item>
           <item row="6" 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="margin">
               <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"/>
+              <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>
          </layout>
         </widget>
        </item>
        <item row="6" 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="3" column="0">
            <widget class="QmitkTensorModelParametersWidget" name="m_TensorWidget2" native="true"/>
           </item>
           <item row="1" column="0">
            <widget class="QmitkZeppelinModelParametersWidget" name="m_ZeppelinWidget2" native="true"/>
           </item>
           <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="2" column="0">
            <widget class="QmitkStickModelParametersWidget" name="m_StickWidget2" native="true"/>
           </item>
          </layout>
         </widget>
        </item>
       </layout>
      </widget>
     </widget>
    </item>
   </layout>
  </widget>
  <customwidgets>
   <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>QmitkDataStorageComboBox</class>
    <extends>QComboBox</extends>
    <header location="global">QmitkDataStorageComboBox.h</header>
   </customwidget>
  </customwidgets>
  <tabstops>
-  <tabstop>tabWidget</tabstop>
   <tabstop>m_CircleButton</tabstop>
   <tabstop>m_FlipButton</tabstop>
   <tabstop>m_RealTimeFibers</tabstop>
-  <tabstop>m_DistributionBox</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_RepetitionsBox</tabstop>
+  <tabstop>m_SignalScaleBox</tabstop>
   <tabstop>m_TEbox</tabstop>
   <tabstop>m_LineReadoutTimeBox</tabstop>
   <tabstop>m_T2starBox</tabstop>
   <tabstop>m_FiberRadius</tabstop>
   <tabstop>m_InterpolationShrink</tabstop>
   <tabstop>m_EnforcePureFiberVoxelsBox</tabstop>
   <tabstop>m_KspaceImageBox</tabstop>
   <tabstop>m_Compartment1Box</tabstop>
   <tabstop>m_Compartment2Box</tabstop>
   <tabstop>m_Compartment3Box</tabstop>
   <tabstop>m_Compartment4Box</tabstop>
   <tabstop>m_Comp4FractionBox</tabstop>
+  <tabstop>m_AddNoise</tabstop>
   <tabstop>m_NoiseLevel</tabstop>
+  <tabstop>m_AddGhosts</tabstop>
+  <tabstop>m_kOffsetBox</tabstop>
+  <tabstop>m_AddDistortions</tabstop>
+  <tabstop>m_FrequencyMapBox</tabstop>
   <tabstop>m_AddGibbsRinging</tabstop>
   <tabstop>m_KspaceUndersamplingBox</tabstop>
+  <tabstop>tabWidget</tabstop>
  </tabstops>
  <resources>
   <include location="../../resources/QmitkDiffusionImaging.qrc"/>
  </resources>
  <connections/>
 </ui>