diff --git a/CMakeExternals/MITKData.cmake b/CMakeExternals/MITKData.cmake
index 77ac2155e0..f06c1546b2 100644
--- a/CMakeExternals/MITKData.cmake
+++ b/CMakeExternals/MITKData.cmake
@@ -1,36 +1,36 @@
 #-----------------------------------------------------------------------------
 # MITK Data
 #-----------------------------------------------------------------------------
 
 # Sanity checks
 if(DEFINED MITK_DATA_DIR AND NOT EXISTS ${MITK_DATA_DIR})
   message(FATAL_ERROR "MITK_DATA_DIR variable is defined but corresponds to non-existing directory")
 endif()
 
 set(proj MITK-Data)
 set(proj_DEPENDENCIES)
 set(MITK-Data_DEPENDS ${proj})
 
 if(BUILD_TESTING)
 
-  set(revision_tag ef63f005) # first 8 characters of hash-tag
+  set(revision_tag 57cfb02c) # first 8 characters of hash-tag
 #                  ^^^^^^^^  these are just to check correct length of hash part
 
   ExternalProject_Add(${proj}
     URL ${MITK_THIRDPARTY_DOWNLOAD_PREFIX_URL}/MITK-Data_${revision_tag}.tar.gz
     UPDATE_COMMAND ""
     CONFIGURE_COMMAND ""
     BUILD_COMMAND ""
     INSTALL_COMMAND ""
     DEPENDS ${proj_DEPENDENCIES}
   )
 
   set(MITK_DATA_DIR ${ep_source_dir}/${proj})
 
 else()
 
   mitkMacroEmptyExternalProject(${proj} "${proj_DEPENDENCIES}")
 
 endif(BUILD_TESTING)
 
 
diff --git a/Modules/DiffusionImaging/FiberTracking/Algorithms/itkTractDensityImageFilter.cpp b/Modules/DiffusionImaging/FiberTracking/Algorithms/itkTractDensityImageFilter.cpp
index 0ac6fb5f9d..c9dccdeb1b 100644
--- a/Modules/DiffusionImaging/FiberTracking/Algorithms/itkTractDensityImageFilter.cpp
+++ b/Modules/DiffusionImaging/FiberTracking/Algorithms/itkTractDensityImageFilter.cpp
@@ -1,237 +1,241 @@
 /*===================================================================
 
 The Medical Imaging Interaction Toolkit (MITK)
 
 Coindex[1]right (c) German Cancer Research Center,
 Division of Medical and Biological Informatics.
 All rights reserved.
 
 This software is distributed WITHOUT ANY WARRANTY; without
 even the implied warranty of MERCHANTABILITY or FITNESS FOR
 A PARTICULAR PURPOSE.
 
 See LICENSE.txt or http://www.mitk.org for details.
 
 ===================================================================*/
 #include "itkTractDensityImageFilter.h"
 
 // VTK
 #include <vtkPolyLine.h>
 #include <vtkCellArray.h>
 #include <vtkCellData.h>
+#include <vtkCell.h>
 
 // misc
 #include <math.h>
 #include <boost/progress.hpp>
 
 namespace itk{
 
 template< class OutputImageType >
 TractDensityImageFilter< OutputImageType >::TractDensityImageFilter()
     : m_InvertImage(false)
     , m_FiberBundle(NULL)
     , m_UpsamplingFactor(1)
     , m_InputImage(NULL)
     , m_BinaryOutput(false)
     , m_UseImageGeometry(false)
     , m_OutputAbsoluteValues(false)
     , m_UseTrilinearInterpolation(false)
 {
 
 }
 
 template< class OutputImageType >
 TractDensityImageFilter< OutputImageType >::~TractDensityImageFilter()
 {
 }
 
 template< class OutputImageType >
 itk::Point<float, 3> TractDensityImageFilter< OutputImageType >::GetItkPoint(double point[3])
 {
     itk::Point<float, 3> itkPoint;
     itkPoint[0] = point[0];
     itkPoint[1] = point[1];
     itkPoint[2] = point[2];
     return itkPoint;
 }
 
 template< class OutputImageType >
 void TractDensityImageFilter< OutputImageType >::GenerateData()
 {
     // generate upsampled image
-  mitk::BaseGeometry::Pointer geometry = m_FiberBundle->GetGeometry();
+    mitk::BaseGeometry::Pointer geometry = m_FiberBundle->GetGeometry();
     typename OutputImageType::Pointer outImage = this->GetOutput();
 
     // calculate new image parameters
     itk::Vector<double,3> newSpacing;
     mitk::Point3D newOrigin;
     itk::Matrix<double, 3, 3> newDirection;
     ImageRegion<3> upsampledRegion;
     if (m_UseImageGeometry && !m_InputImage.IsNull())
     {
         MITK_INFO << "TractDensityImageFilter: using image geometry";
         newSpacing = m_InputImage->GetSpacing()/m_UpsamplingFactor;
         upsampledRegion = m_InputImage->GetLargestPossibleRegion();
         newOrigin = m_InputImage->GetOrigin();
         typename OutputImageType::RegionType::SizeType size = upsampledRegion.GetSize();
         size[0] *= m_UpsamplingFactor;
         size[1] *= m_UpsamplingFactor;
         size[2] *= m_UpsamplingFactor;
         upsampledRegion.SetSize(size);
         newDirection = m_InputImage->GetDirection();
     }
     else
     {
         MITK_INFO << "TractDensityImageFilter: using fiber bundle geometry";
         newSpacing = geometry->GetSpacing()/m_UpsamplingFactor;
         newOrigin = geometry->GetOrigin();
         mitk::Geometry3D::BoundsArrayType bounds = geometry->GetBounds();
         newOrigin[0] += bounds.GetElement(0);
         newOrigin[1] += bounds.GetElement(2);
         newOrigin[2] += bounds.GetElement(4);
 
         for (int i=0; i<3; i++)
             for (int j=0; j<3; j++)
                 newDirection[j][i] = geometry->GetMatrixColumn(i)[j];
         upsampledRegion.SetSize(0, geometry->GetExtent(0)*m_UpsamplingFactor);
         upsampledRegion.SetSize(1, geometry->GetExtent(1)*m_UpsamplingFactor);
         upsampledRegion.SetSize(2, geometry->GetExtent(2)*m_UpsamplingFactor);
     }
     typename OutputImageType::RegionType::SizeType upsampledSize = upsampledRegion.GetSize();
 
     // apply new image parameters
     outImage->SetSpacing( newSpacing );
     outImage->SetOrigin( newOrigin );
     outImage->SetDirection( newDirection );
-    outImage->SetRegions( upsampledRegion );
+    outImage->SetLargestPossibleRegion( upsampledRegion );
+    outImage->SetBufferedRegion( upsampledRegion );
+    outImage->SetRequestedRegion( upsampledRegion );
     outImage->Allocate();
     outImage->FillBuffer(0.0);
 
     int w = upsampledSize[0];
     int h = upsampledSize[1];
     int d = upsampledSize[2];
 
     // set/initialize output
     OutPixelType* outImageBufferPointer = (OutPixelType*)outImage->GetBufferPointer();
 
     // resample fiber bundle
     float minSpacing = 1;
     if(newSpacing[0]<newSpacing[1] && newSpacing[0]<newSpacing[2])
         minSpacing = newSpacing[0];
     else if (newSpacing[1] < newSpacing[2])
         minSpacing = newSpacing[1];
     else
         minSpacing = newSpacing[2];
 
     MITK_INFO << "TractDensityImageFilter: resampling fibers to ensure sufficient voxel coverage";
     m_FiberBundle = m_FiberBundle->GetDeepCopy();
-    m_FiberBundle->ResampleLinear(minSpacing/10);
+    m_FiberBundle->ResampleSpline(minSpacing/10);
 
     MITK_INFO << "TractDensityImageFilter: starting image generation";
+
     vtkSmartPointer<vtkPolyData> fiberPolyData = m_FiberBundle->GetFiberPolyData();
     vtkSmartPointer<vtkCellArray> vLines = fiberPolyData->GetLines();
     vLines->InitTraversal();
     int numFibers = m_FiberBundle->GetNumFibers();
     boost::progress_display disp(numFibers);
     for( int i=0; i<numFibers; i++ )
     {
         ++disp;
         vtkIdType   numPoints(0);
         vtkIdType*  points(NULL);
         vLines->GetNextCell ( numPoints, points );
 
         // fill output image
         for( int j=0; j<numPoints; j++)
         {
             itk::Point<float, 3> vertex = GetItkPoint(fiberPolyData->GetPoint(points[j]));
             itk::Index<3> index;
             itk::ContinuousIndex<float, 3> contIndex;
             outImage->TransformPhysicalPointToIndex(vertex, index);
             outImage->TransformPhysicalPointToContinuousIndex(vertex, contIndex);
 
-            if (!m_UseTrilinearInterpolation)
+            if (!m_UseTrilinearInterpolation && outImage->GetLargestPossibleRegion().IsInside(index))
             {
                 if (m_BinaryOutput)
                     outImage->SetPixel(index, 1);
                 else
                     outImage->SetPixel(index, outImage->GetPixel(index)+0.01);
                 continue;
             }
 
             float frac_x = contIndex[0] - index[0];
             float frac_y = contIndex[1] - index[1];
             float frac_z = contIndex[2] - index[2];
 
             if (frac_x<0)
             {
                 index[0] -= 1;
                 frac_x += 1;
             }
             if (frac_y<0)
             {
                 index[1] -= 1;
                 frac_y += 1;
             }
             if (frac_z<0)
             {
                 index[2] -= 1;
                 frac_z += 1;
             }
 
             frac_x = 1-frac_x;
             frac_y = 1-frac_y;
             frac_z = 1-frac_z;
 
             // int coordinates inside image?
             if (index[0] < 0 || index[0] >= w-1)
                 continue;
             if (index[1] < 0 || index[1] >= h-1)
                 continue;
             if (index[2] < 0 || index[2] >= d-1)
                 continue;
 
             if (m_BinaryOutput)
             {
                 outImageBufferPointer[( index[0]   + w*(index[1]  + h*index[2]  ))] = 1;
                 outImageBufferPointer[( index[0]   + w*(index[1]+1+ h*index[2]  ))] = 1;
                 outImageBufferPointer[( index[0]   + w*(index[1]  + h*index[2]+h))] = 1;
                 outImageBufferPointer[( index[0]   + w*(index[1]+1+ h*index[2]+h))] = 1;
                 outImageBufferPointer[( index[0]+1 + w*(index[1]  + h*index[2]  ))] = 1;
                 outImageBufferPointer[( index[0]+1 + w*(index[1]  + h*index[2]+h))] = 1;
                 outImageBufferPointer[( index[0]+1 + w*(index[1]+1+ h*index[2]  ))] = 1;
                 outImageBufferPointer[( index[0]+1 + w*(index[1]+1+ h*index[2]+h))] = 1;
             }
             else
             {
                 outImageBufferPointer[( index[0]   + w*(index[1]  + h*index[2]  ))] += (  frac_x)*(  frac_y)*(  frac_z);
                 outImageBufferPointer[( index[0]   + w*(index[1]+1+ h*index[2]  ))] += (  frac_x)*(1-frac_y)*(  frac_z);
                 outImageBufferPointer[( index[0]   + w*(index[1]  + h*index[2]+h))] += (  frac_x)*(  frac_y)*(1-frac_z);
                 outImageBufferPointer[( index[0]   + w*(index[1]+1+ h*index[2]+h))] += (  frac_x)*(1-frac_y)*(1-frac_z);
                 outImageBufferPointer[( index[0]+1 + w*(index[1]  + h*index[2]  ))] += (1-frac_x)*(  frac_y)*(  frac_z);
                 outImageBufferPointer[( index[0]+1 + w*(index[1]  + h*index[2]+h))] += (1-frac_x)*(  frac_y)*(1-frac_z);
                 outImageBufferPointer[( index[0]+1 + w*(index[1]+1+ h*index[2]  ))] += (1-frac_x)*(1-frac_y)*(  frac_z);
                 outImageBufferPointer[( index[0]+1 + w*(index[1]+1+ h*index[2]+h))] += (1-frac_x)*(1-frac_y)*(1-frac_z);
             }
         }
     }
 
     if (!m_OutputAbsoluteValues && !m_BinaryOutput)
     {
         MITK_INFO << "TractDensityImageFilter: max-normalizing output image";
         OutPixelType max = 0;
         for (int i=0; i<w*h*d; i++)
             if (max < outImageBufferPointer[i])
                 max = outImageBufferPointer[i];
         if (max>0)
             for (int i=0; i<w*h*d; i++)
                 outImageBufferPointer[i] /= max;
     }
     if (m_InvertImage)
     {
         MITK_INFO << "TractDensityImageFilter: inverting image";
         for (int i=0; i<w*h*d; i++)
             outImageBufferPointer[i] = 1-outImageBufferPointer[i];
     }
     MITK_INFO << "TractDensityImageFilter: finished processing";
 }
 }
diff --git a/Modules/DiffusionImaging/FiberTracking/Algorithms/itkTractsToDWIImageFilter.cpp b/Modules/DiffusionImaging/FiberTracking/Algorithms/itkTractsToDWIImageFilter.cpp
index b8862ffe58..1805a97fb1 100755
--- a/Modules/DiffusionImaging/FiberTracking/Algorithms/itkTractsToDWIImageFilter.cpp
+++ b/Modules/DiffusionImaging/FiberTracking/Algorithms/itkTractsToDWIImageFilter.cpp
@@ -1,1301 +1,1301 @@
 /*===================================================================
 
 The Medical Imaging Interaction Toolkit (MITK)
 
 Copyright (c) German Cancer Research Center,
 Division of Medical and Biological Informatics.
 All rights reserved.
 
 This software is distributed WITHOUT ANY WARRANTY; without
 even the implied warranty of MERCHANTABILITY or FITNESS FOR
 A PARTICULAR PURPOSE.
 
 See LICENSE.txt or http://www.mitk.org for details.
 
 ===================================================================*/
 
 #include "itkTractsToDWIImageFilter.h"
 #include <boost/progress.hpp>
 #include <vtkSmartPointer.h>
 #include <vtkPolyData.h>
 #include <vtkCellArray.h>
 #include <vtkPoints.h>
 #include <vtkPolyLine.h>
 #include <itkImageRegionIteratorWithIndex.h>
 #include <itkResampleImageFilter.h>
 #include <itkNearestNeighborInterpolateImageFunction.h>
 #include <itkBSplineInterpolateImageFunction.h>
 #include <itkCastImageFilter.h>
 #include <itkImageFileWriter.h>
 #include <itkRescaleIntensityImageFilter.h>
 #include <itkWindowedSincInterpolateImageFunction.h>
 #include <itkResampleDwiImageFilter.h>
 #include <itkKspaceImageFilter.h>
 #include <itkDftImageFilter.h>
 #include <itkAddImageFilter.h>
 #include <itkConstantPadImageFilter.h>
 #include <itkCropImageFilter.h>
 #include <mitkAstroStickModel.h>
 #include <vtkTransform.h>
 #include <iostream>
 #include <fstream>
 #include <itkImageDuplicator.h>
 #include <itksys/SystemTools.hxx>
 #include <mitkIOUtil.h>
 #include <itkDiffusionTensor3DReconstructionImageFilter.h>
 #include <itkDiffusionTensor3D.h>
 #include <itkTractDensityImageFilter.h>
 #include <boost/lexical_cast.hpp>
 #include <itkTractsToVectorImageFilter.h>
 
 namespace itk
 {
 
 template< class PixelType >
 TractsToDWIImageFilter< PixelType >::TractsToDWIImageFilter()
     : m_FiberBundle(NULL)
     , m_StatusText("")
     , m_UseConstantRandSeed(false)
     , m_RandGen(itk::Statistics::MersenneTwisterRandomVariateGenerator::New())
 {
     m_RandGen->SetSeed();
 }
 
 template< class PixelType >
 TractsToDWIImageFilter< PixelType >::~TractsToDWIImageFilter()
 {
 
 }
 
 template< class PixelType >
 TractsToDWIImageFilter< PixelType >::DoubleDwiType::Pointer TractsToDWIImageFilter< PixelType >::DoKspaceStuff( std::vector< DoubleDwiType::Pointer >& images )
 {
     int numFiberCompartments = m_Parameters.m_FiberModelList.size();
     // create slice object
     ImageRegion<2> sliceRegion;
     sliceRegion.SetSize(0, m_UpsampledImageRegion.GetSize()[0]);
     sliceRegion.SetSize(1, m_UpsampledImageRegion.GetSize()[1]);
     Vector< double, 2 > sliceSpacing;
     sliceSpacing[0] = m_UpsampledSpacing[0];
     sliceSpacing[1] = m_UpsampledSpacing[1];
 
     // frequency map slice
     SliceType::Pointer fMapSlice = NULL;
     if (m_Parameters.m_SignalGen.m_FrequencyMap.IsNotNull())
     {
         fMapSlice = SliceType::New();
         ImageRegion<2> region;
         region.SetSize(0, m_UpsampledImageRegion.GetSize()[0]);
         region.SetSize(1, m_UpsampledImageRegion.GetSize()[1]);
         fMapSlice->SetLargestPossibleRegion( region );
         fMapSlice->SetBufferedRegion( region );
         fMapSlice->SetRequestedRegion( region );
         fMapSlice->Allocate();
         fMapSlice->FillBuffer(0.0);
     }
 
     DoubleDwiType::Pointer newImage = DoubleDwiType::New();
     newImage->SetSpacing( m_Parameters.m_SignalGen.m_ImageSpacing );
     newImage->SetOrigin( m_Parameters.m_SignalGen.m_ImageOrigin );
     newImage->SetDirection( m_Parameters.m_SignalGen.m_ImageDirection );
     newImage->SetLargestPossibleRegion( m_Parameters.m_SignalGen.m_ImageRegion );
     newImage->SetBufferedRegion( m_Parameters.m_SignalGen.m_ImageRegion );
     newImage->SetRequestedRegion( m_Parameters.m_SignalGen.m_ImageRegion );
     newImage->SetVectorLength( images.at(0)->GetVectorLength() );
     newImage->Allocate();
 
     std::vector< unsigned int > spikeVolume;
     for (unsigned int i=0; i<m_Parameters.m_SignalGen.m_Spikes; i++)
         spikeVolume.push_back(m_RandGen->GetIntegerVariate()%images.at(0)->GetVectorLength());
     std::sort (spikeVolume.begin(), spikeVolume.end());
     std::reverse (spikeVolume.begin(), spikeVolume.end());
 
     m_StatusText += "0%   10   20   30   40   50   60   70   80   90   100%\n";
     m_StatusText += "|----|----|----|----|----|----|----|----|----|----|\n*";
     unsigned long lastTick = 0;
 
     boost::progress_display disp(2*images.at(0)->GetVectorLength()*images.at(0)->GetLargestPossibleRegion().GetSize(2));
     for (unsigned int g=0; g<images.at(0)->GetVectorLength(); g++)
     {
         std::vector< unsigned int > spikeSlice;
         while (!spikeVolume.empty() && spikeVolume.back()==g)
         {
             spikeSlice.push_back(m_RandGen->GetIntegerVariate()%images.at(0)->GetLargestPossibleRegion().GetSize(2));
             spikeVolume.pop_back();
         }
         std::sort (spikeSlice.begin(), spikeSlice.end());
         std::reverse (spikeSlice.begin(), spikeSlice.end());
 
         for (unsigned int z=0; z<images.at(0)->GetLargestPossibleRegion().GetSize(2); z++)
         {
             std::vector< SliceType::Pointer > compartmentSlices;
             std::vector< double > t2Vector;
 
             for (unsigned int i=0; i<images.size(); i++)
             {
                 DiffusionSignalModel<double>* signalModel;
                 if (i<numFiberCompartments)
                     signalModel = m_Parameters.m_FiberModelList.at(i);
                 else
                     signalModel = m_Parameters.m_NonFiberModelList.at(i-numFiberCompartments);
 
                 SliceType::Pointer slice = SliceType::New();
                 slice->SetLargestPossibleRegion( sliceRegion );
                 slice->SetBufferedRegion( sliceRegion );
                 slice->SetRequestedRegion( sliceRegion );
                 slice->SetSpacing(sliceSpacing);
                 slice->Allocate();
                 slice->FillBuffer(0.0);
 
                 // extract slice from channel g
                 for (unsigned int y=0; y<images.at(0)->GetLargestPossibleRegion().GetSize(1); y++)
                     for (unsigned int x=0; x<images.at(0)->GetLargestPossibleRegion().GetSize(0); x++)
                     {
                         SliceType::IndexType index2D; index2D[0]=x; index2D[1]=y;
                         DoubleDwiType::IndexType index3D; index3D[0]=x; index3D[1]=y; index3D[2]=z;
 
                         slice->SetPixel(index2D, images.at(i)->GetPixel(index3D)[g]);
 
                         if (fMapSlice.IsNotNull() && i==0)
                             fMapSlice->SetPixel(index2D, m_Parameters.m_SignalGen.m_FrequencyMap->GetPixel(index3D));
                     }
 
                 compartmentSlices.push_back(slice);
                 t2Vector.push_back(signalModel->GetT2());
             }
 
             if (this->GetAbortGenerateData())
                 return NULL;
 
             // create k-sapce (inverse fourier transform slices)
             itk::Size<2> outSize; outSize.SetElement(0, m_Parameters.m_SignalGen.m_ImageRegion.GetSize(0)); outSize.SetElement(1, m_Parameters.m_SignalGen.m_ImageRegion.GetSize(1));
             itk::KspaceImageFilter< SliceType::PixelType >::Pointer idft = itk::KspaceImageFilter< SliceType::PixelType >::New();
             idft->SetCompartmentImages(compartmentSlices);
             idft->SetT2(t2Vector);
             idft->SetUseConstantRandSeed(m_UseConstantRandSeed);
             idft->SetParameters(m_Parameters);
             idft->SetZ((double)z-(double)images.at(0)->GetLargestPossibleRegion().GetSize(2)/2.0);
             idft->SetDiffusionGradientDirection(m_Parameters.m_SignalGen.GetGradientDirection(g));
             idft->SetFrequencyMapSlice(fMapSlice);
             idft->SetOutSize(outSize);
             int numSpikes = 0;
             while (!spikeSlice.empty() && spikeSlice.back()==z)
             {
                 numSpikes++;
                 spikeSlice.pop_back();
             }
             idft->SetSpikesPerSlice(numSpikes);
             idft->Update();
 
             ComplexSliceType::Pointer fSlice;
             fSlice = idft->GetOutput();
 
             ++disp;
             unsigned long newTick = 50*disp.count()/disp.expected_count();
             for (unsigned  long tick = 0; tick<(newTick-lastTick); tick++)
                 m_StatusText += "*";
             lastTick = newTick;
 
             // fourier transform slice
             SliceType::Pointer newSlice;
             itk::DftImageFilter< SliceType::PixelType >::Pointer dft = itk::DftImageFilter< SliceType::PixelType >::New();
             dft->SetInput(fSlice);
             dft->Update();
             newSlice = dft->GetOutput();
 
             // put slice back into channel g
             for (unsigned int y=0; y<fSlice->GetLargestPossibleRegion().GetSize(1); y++)
                 for (unsigned int x=0; x<fSlice->GetLargestPossibleRegion().GetSize(0); x++)
                 {
                     DoubleDwiType::IndexType index3D; index3D[0]=x; index3D[1]=y; index3D[2]=z;
                     SliceType::IndexType index2D; index2D[0]=x; index2D[1]=y;
 
                     DoubleDwiType::PixelType pix3D = newImage->GetPixel(index3D);
                     pix3D[g] = newSlice->GetPixel(index2D);
                     newImage->SetPixel(index3D, pix3D);
                 }
             ++disp;
             newTick = 50*disp.count()/disp.expected_count();
             for (unsigned long tick = 0; tick<(newTick-lastTick); tick++)
                 m_StatusText += "*";
             lastTick = newTick;
         }
     }
     m_StatusText += "\n\n";
     return newImage;
 }
 
 template< class PixelType >
 void TractsToDWIImageFilter< PixelType >::GenerateData()
 {
     m_TimeProbe.Start();
     m_StatusText = "Starting simulation\n";
 
     // check input data
     if (m_FiberBundle.IsNull())
         itkExceptionMacro("Input fiber bundle is NULL!");
 
     if (m_Parameters.m_FiberModelList.empty())
         itkExceptionMacro("No diffusion model for fiber compartments defined!");
 
     if (m_Parameters.m_NonFiberModelList.empty())
         itkExceptionMacro("No diffusion model for non-fiber compartments defined!");
 
     int baselineIndex = m_Parameters.m_SignalGen.GetFirstBaselineIndex();
     if (baselineIndex<0)
         itkExceptionMacro("No baseline index found!");
 
     if (!m_Parameters.m_SignalGen.m_SimulateKspaceAcquisition)
         m_Parameters.m_SignalGen.m_DoAddGibbsRinging = false;
 
     if (m_UseConstantRandSeed)  // always generate the same random numbers?
         m_RandGen->SetSeed(0);
     else
         m_RandGen->SetSeed();
 
     // initialize output dwi image
     ImageRegion<3> croppedRegion = m_Parameters.m_SignalGen.m_ImageRegion; croppedRegion.SetSize(1, croppedRegion.GetSize(1)*m_Parameters.m_SignalGen.m_CroppingFactor);
     itk::Point<double,3> shiftedOrigin = m_Parameters.m_SignalGen.m_ImageOrigin; shiftedOrigin[1] += (m_Parameters.m_SignalGen.m_ImageRegion.GetSize(1)-croppedRegion.GetSize(1))*m_Parameters.m_SignalGen.m_ImageSpacing[1]/2;
     typename OutputImageType::Pointer outImage = OutputImageType::New();
     outImage->SetSpacing( m_Parameters.m_SignalGen.m_ImageSpacing );
     outImage->SetOrigin( shiftedOrigin );
     outImage->SetDirection( m_Parameters.m_SignalGen.m_ImageDirection );
     outImage->SetLargestPossibleRegion( croppedRegion );
     outImage->SetBufferedRegion( croppedRegion );
     outImage->SetRequestedRegion( croppedRegion );
     outImage->SetVectorLength( m_Parameters.m_SignalGen.GetNumVolumes() );
     outImage->Allocate();
     typename OutputImageType::PixelType temp;
     temp.SetSize(m_Parameters.m_SignalGen.GetNumVolumes());
     temp.Fill(0.0);
     outImage->FillBuffer(temp);
 
     // ADJUST GEOMETRY FOR FURTHER PROCESSING
     // is input slize size a power of two?
     unsigned int x=m_Parameters.m_SignalGen.m_ImageRegion.GetSize(0); unsigned int y=m_Parameters.m_SignalGen.m_ImageRegion.GetSize(1);
     ItkDoubleImgType::SizeType pad; pad[0]=x%2; pad[1]=y%2; pad[2]=0;
     m_Parameters.m_SignalGen.m_ImageRegion.SetSize(0, x+pad[0]);
     m_Parameters.m_SignalGen.m_ImageRegion.SetSize(1, y+pad[1]);
     if (m_Parameters.m_SignalGen.m_FrequencyMap.IsNotNull() && (pad[0]>0 || pad[1]>0))
     {
         itk::ConstantPadImageFilter<ItkDoubleImgType, ItkDoubleImgType>::Pointer zeroPadder = itk::ConstantPadImageFilter<ItkDoubleImgType, ItkDoubleImgType>::New();
         zeroPadder->SetInput(m_Parameters.m_SignalGen.m_FrequencyMap);
         zeroPadder->SetConstant(0);
         zeroPadder->SetPadUpperBound(pad);
         zeroPadder->Update();
         m_Parameters.m_SignalGen.m_FrequencyMap = zeroPadder->GetOutput();
     }
     if (m_Parameters.m_SignalGen.m_MaskImage.IsNotNull() && (pad[0]>0 || pad[1]>0))
     {
         itk::ConstantPadImageFilter<ItkUcharImgType, ItkUcharImgType>::Pointer zeroPadder = itk::ConstantPadImageFilter<ItkUcharImgType, ItkUcharImgType>::New();
         zeroPadder->SetInput(m_Parameters.m_SignalGen.m_MaskImage);
         zeroPadder->SetConstant(0);
         zeroPadder->SetPadUpperBound(pad);
         zeroPadder->Update();
         m_Parameters.m_SignalGen.m_MaskImage = zeroPadder->GetOutput();
     }
 
     // Apply in-plane upsampling for Gibbs ringing artifact
     double upsampling = 1;
     if (m_Parameters.m_SignalGen.m_DoAddGibbsRinging)
         upsampling = 2;
     m_UpsampledSpacing = m_Parameters.m_SignalGen.m_ImageSpacing;
     m_UpsampledSpacing[0] /= upsampling;
     m_UpsampledSpacing[1] /= upsampling;
     m_UpsampledImageRegion = m_Parameters.m_SignalGen.m_ImageRegion;
     m_UpsampledImageRegion.SetSize(0, m_Parameters.m_SignalGen.m_ImageRegion.GetSize()[0]*upsampling);
     m_UpsampledImageRegion.SetSize(1, m_Parameters.m_SignalGen.m_ImageRegion.GetSize()[1]*upsampling);
     m_UpsampledOrigin = m_Parameters.m_SignalGen.m_ImageOrigin;
     m_UpsampledOrigin[0] -= m_Parameters.m_SignalGen.m_ImageSpacing[0]/2; m_UpsampledOrigin[0] += m_UpsampledSpacing[0]/2;
     m_UpsampledOrigin[1] -= m_Parameters.m_SignalGen.m_ImageSpacing[1]/2; m_UpsampledOrigin[1] += m_UpsampledSpacing[1]/2;
     m_UpsampledOrigin[2] -= m_Parameters.m_SignalGen.m_ImageSpacing[2]/2; m_UpsampledOrigin[2] += m_UpsampledSpacing[2]/2;
 
     // generate double images to store the individual compartment signals
     m_CompartmentImages.clear();
     int numFiberCompartments = m_Parameters.m_FiberModelList.size();
     int numNonFiberCompartments = m_Parameters.m_NonFiberModelList.size();
 
     for (int i=0; i<numFiberCompartments+numNonFiberCompartments; i++)
     {
         DoubleDwiType::Pointer doubleDwi = DoubleDwiType::New();
         doubleDwi->SetSpacing( m_UpsampledSpacing );
         doubleDwi->SetOrigin( m_UpsampledOrigin );
         doubleDwi->SetDirection( m_Parameters.m_SignalGen.m_ImageDirection );
         doubleDwi->SetLargestPossibleRegion( m_UpsampledImageRegion );
         doubleDwi->SetBufferedRegion( m_UpsampledImageRegion );
         doubleDwi->SetRequestedRegion( m_UpsampledImageRegion );
         doubleDwi->SetVectorLength( m_Parameters.m_SignalGen.GetNumVolumes() );
         doubleDwi->Allocate();
         DoubleDwiType::PixelType pix;
         pix.SetSize(m_Parameters.m_SignalGen.GetNumVolumes());
         pix.Fill(0.0);
         doubleDwi->FillBuffer(pix);
         m_CompartmentImages.push_back(doubleDwi);
     }
 
     // initialize output volume fraction images
     m_VolumeFractions.clear();
     for (int i=0; i<numFiberCompartments+numNonFiberCompartments; i++)
     {
         ItkDoubleImgType::Pointer doubleImg = ItkDoubleImgType::New();
         doubleImg->SetSpacing( m_UpsampledSpacing );
         doubleImg->SetOrigin( m_UpsampledOrigin );
         doubleImg->SetDirection( m_Parameters.m_SignalGen.m_ImageDirection );
         doubleImg->SetLargestPossibleRegion( m_UpsampledImageRegion );
         doubleImg->SetBufferedRegion( m_UpsampledImageRegion );
         doubleImg->SetRequestedRegion( m_UpsampledImageRegion );
         doubleImg->Allocate();
         doubleImg->FillBuffer(0);
         m_VolumeFractions.push_back(doubleImg);
     }
 
     // get volume fraction images
     ItkDoubleImgType::Pointer sumImage = ItkDoubleImgType::New();
     bool foundVolumeFractionImage = false;
 
     for (int i=0; i<numNonFiberCompartments; i++)  // look if a volume fraction image is set
     {
         if (m_Parameters.m_NonFiberModelList[i]->GetVolumeFractionImage().IsNotNull())
         {
             foundVolumeFractionImage = true;
 
             itk::ConstantPadImageFilter<ItkDoubleImgType, ItkDoubleImgType>::Pointer zeroPadder = itk::ConstantPadImageFilter<ItkDoubleImgType, ItkDoubleImgType>::New();
             zeroPadder->SetInput(m_Parameters.m_NonFiberModelList[i]->GetVolumeFractionImage());
             zeroPadder->SetConstant(0);
             zeroPadder->SetPadUpperBound(pad);
             zeroPadder->Update();
             m_Parameters.m_NonFiberModelList[i]->SetVolumeFractionImage(zeroPadder->GetOutput());
 
             sumImage->SetSpacing( m_Parameters.m_NonFiberModelList[i]->GetVolumeFractionImage()->GetSpacing() );
             sumImage->SetOrigin( m_Parameters.m_NonFiberModelList[i]->GetVolumeFractionImage()->GetOrigin() );
             sumImage->SetDirection( m_Parameters.m_NonFiberModelList[i]->GetVolumeFractionImage()->GetDirection() );
             sumImage->SetLargestPossibleRegion( m_Parameters.m_NonFiberModelList[i]->GetVolumeFractionImage()->GetLargestPossibleRegion() );
             sumImage->SetBufferedRegion( m_Parameters.m_NonFiberModelList[i]->GetVolumeFractionImage()->GetLargestPossibleRegion() );
             sumImage->SetRequestedRegion( m_Parameters.m_NonFiberModelList[i]->GetVolumeFractionImage()->GetLargestPossibleRegion() );
             sumImage->Allocate();
             sumImage->FillBuffer(0);
             break;
         }
     }
     if (!foundVolumeFractionImage)
     {
         sumImage->SetSpacing( m_UpsampledSpacing );
         sumImage->SetOrigin( m_UpsampledOrigin );
         sumImage->SetDirection( m_Parameters.m_SignalGen.m_ImageDirection );
         sumImage->SetLargestPossibleRegion( m_UpsampledImageRegion );
         sumImage->SetBufferedRegion( m_UpsampledImageRegion );
         sumImage->SetRequestedRegion( m_UpsampledImageRegion );
         sumImage->Allocate();
         sumImage->FillBuffer(0.0);
     }
     for (int i=0; i<numNonFiberCompartments; i++)
     {
         if (m_Parameters.m_NonFiberModelList[i]->GetVolumeFractionImage().IsNull())
         {
             ItkDoubleImgType::Pointer doubleImg = ItkDoubleImgType::New();
             doubleImg->SetSpacing( sumImage->GetSpacing() );
             doubleImg->SetOrigin( sumImage->GetOrigin() );
             doubleImg->SetDirection( sumImage->GetDirection() );
             doubleImg->SetLargestPossibleRegion( sumImage->GetLargestPossibleRegion() );
             doubleImg->SetBufferedRegion( sumImage->GetLargestPossibleRegion() );
             doubleImg->SetRequestedRegion( sumImage->GetLargestPossibleRegion() );
             doubleImg->Allocate();
             doubleImg->FillBuffer(1.0/numNonFiberCompartments);
             m_Parameters.m_NonFiberModelList[i]->SetVolumeFractionImage(doubleImg);
         }
         ImageRegionIterator<ItkDoubleImgType> it(m_Parameters.m_NonFiberModelList[i]->GetVolumeFractionImage(), m_Parameters.m_NonFiberModelList[i]->GetVolumeFractionImage()->GetLargestPossibleRegion());
         while(!it.IsAtEnd())
         {
             sumImage->SetPixel(it.GetIndex(), sumImage->GetPixel(it.GetIndex())+it.Get());
             ++it;
         }
     }
     for (int i=0; i<numNonFiberCompartments; i++)
     {
         ImageRegionIterator<ItkDoubleImgType> it(m_Parameters.m_NonFiberModelList[i]->GetVolumeFractionImage(), m_Parameters.m_NonFiberModelList[i]->GetVolumeFractionImage()->GetLargestPossibleRegion());
         while(!it.IsAtEnd())
         {
             if (sumImage->GetPixel(it.GetIndex())>0)
                 it.Set(it.Get()/sumImage->GetPixel(it.GetIndex()));
             ++it;
         }
     }
 
     // resample mask image and frequency map to fit upsampled geometry
     if (m_Parameters.m_SignalGen.m_DoAddGibbsRinging)
     {
         if (m_Parameters.m_SignalGen.m_MaskImage.IsNotNull())
         {
             // rescale mask image (otherwise there are problems with the resampling)
             itk::RescaleIntensityImageFilter<ItkUcharImgType,ItkUcharImgType>::Pointer rescaler = itk::RescaleIntensityImageFilter<ItkUcharImgType,ItkUcharImgType>::New();
             rescaler->SetInput(0,m_Parameters.m_SignalGen.m_MaskImage);
             rescaler->SetOutputMaximum(100);
             rescaler->SetOutputMinimum(0);
             rescaler->Update();
 
             // resample mask image
             itk::ResampleImageFilter<ItkUcharImgType, ItkUcharImgType>::Pointer resampler = itk::ResampleImageFilter<ItkUcharImgType, ItkUcharImgType>::New();
             resampler->SetInput(rescaler->GetOutput());
             resampler->SetOutputParametersFromImage(m_Parameters.m_SignalGen.m_MaskImage);
             resampler->SetSize(m_UpsampledImageRegion.GetSize());
             resampler->SetOutputSpacing(m_UpsampledSpacing);
             resampler->SetOutputOrigin(m_UpsampledOrigin);
             itk::NearestNeighborInterpolateImageFunction<ItkUcharImgType, double>::Pointer nn_interpolator
                     = itk::NearestNeighborInterpolateImageFunction<ItkUcharImgType, double>::New();
             resampler->SetInterpolator(nn_interpolator);
             resampler->Update();
             m_Parameters.m_SignalGen.m_MaskImage = resampler->GetOutput();
 
             itk::ImageFileWriter<ItkUcharImgType>::Pointer w = itk::ImageFileWriter<ItkUcharImgType>::New();
             w->SetFileName("/local/mask_ups.nrrd");
             w->SetInput(m_Parameters.m_SignalGen.m_MaskImage);
             w->Update();
         }
         // resample frequency map
         if (m_Parameters.m_SignalGen.m_FrequencyMap.IsNotNull())
         {
             itk::ResampleImageFilter<ItkDoubleImgType, ItkDoubleImgType>::Pointer resampler = itk::ResampleImageFilter<ItkDoubleImgType, ItkDoubleImgType>::New();
             resampler->SetInput(m_Parameters.m_SignalGen.m_FrequencyMap);
             resampler->SetOutputParametersFromImage(m_Parameters.m_SignalGen.m_FrequencyMap);
             resampler->SetSize(m_UpsampledImageRegion.GetSize());
             resampler->SetOutputSpacing(m_UpsampledSpacing);
             resampler->SetOutputOrigin(m_UpsampledOrigin);
             itk::NearestNeighborInterpolateImageFunction<ItkDoubleImgType, double>::Pointer nn_interpolator
                     = itk::NearestNeighborInterpolateImageFunction<ItkDoubleImgType, double>::New();
             resampler->SetInterpolator(nn_interpolator);
             resampler->Update();
             m_Parameters.m_SignalGen.m_FrequencyMap = resampler->GetOutput();
         }
     }
 
     // no input tissue mask is set -> create default
     m_MaskImageSet = true;
     if (m_Parameters.m_SignalGen.m_MaskImage.IsNull())
     {
         m_StatusText += "No tissue mask set\n";
         MITK_INFO << "No tissue mask set";
         m_Parameters.m_SignalGen.m_MaskImage = ItkUcharImgType::New();
         m_Parameters.m_SignalGen.m_MaskImage->SetSpacing( m_UpsampledSpacing );
         m_Parameters.m_SignalGen.m_MaskImage->SetOrigin( m_UpsampledOrigin );
         m_Parameters.m_SignalGen.m_MaskImage->SetDirection( m_Parameters.m_SignalGen.m_ImageDirection );
         m_Parameters.m_SignalGen.m_MaskImage->SetLargestPossibleRegion( m_UpsampledImageRegion );
         m_Parameters.m_SignalGen.m_MaskImage->SetBufferedRegion( m_UpsampledImageRegion );
         m_Parameters.m_SignalGen.m_MaskImage->SetRequestedRegion( m_UpsampledImageRegion );
         m_Parameters.m_SignalGen.m_MaskImage->Allocate();
         m_Parameters.m_SignalGen.m_MaskImage->FillBuffer(1);
         m_MaskImageSet = false;
     }
     else
     {
         m_StatusText += "Using tissue mask\n";
         MITK_INFO << "Using tissue mask";
     }
 
     m_Parameters.m_SignalGen.m_ImageRegion = croppedRegion;
     x=m_Parameters.m_SignalGen.m_ImageRegion.GetSize(0); y=m_Parameters.m_SignalGen.m_ImageRegion.GetSize(1);
     if ( x%2 == 1 )
         m_Parameters.m_SignalGen.m_ImageRegion.SetSize(0, x+1);
     if ( y%2 == 1 )
         m_Parameters.m_SignalGen.m_ImageRegion.SetSize(1, y+1);
 
     // resample fiber bundle for sufficient voxel coverage
     m_StatusText += "\n"+this->GetTime()+" > Resampling fibers ...\n";
     double segmentVolume = 0.0001;
     float minSpacing = 1;
     if(m_UpsampledSpacing[0]<m_UpsampledSpacing[1] && m_UpsampledSpacing[0]<m_UpsampledSpacing[2])
         minSpacing = m_UpsampledSpacing[0];
     else if (m_UpsampledSpacing[1] < m_UpsampledSpacing[2])
         minSpacing = m_UpsampledSpacing[1];
     else
         minSpacing = m_UpsampledSpacing[2];
     m_FiberBundleWorkingCopy = m_FiberBundle->GetDeepCopy();
     double volumeAccuracy = 10;
-    m_FiberBundleWorkingCopy->ResampleLinear(minSpacing/volumeAccuracy);
+    m_FiberBundleWorkingCopy->ResampleSpline(minSpacing/volumeAccuracy);
     double mmRadius = m_Parameters.m_SignalGen.m_AxonRadius/1000;
     if (mmRadius>0)
         segmentVolume = M_PI*mmRadius*mmRadius*minSpacing/volumeAccuracy;
 
     double maxVolume = 0;
     m_VoxelVolume = m_UpsampledSpacing[0]*m_UpsampledSpacing[1]*m_UpsampledSpacing[2];
 
     if (m_Parameters.m_SignalGen.m_DoAddMotion)
     {
         std::string fileName = "fiberfox_motion_0.log";
         std::string filePath = mitk::IOUtil::GetTempPath();
         if (m_Parameters.m_Misc.m_OutputPath.size()>0)
             filePath = m_Parameters.m_Misc.m_OutputPath;
 
         int c = 1;
 
         while (itksys::SystemTools::FileExists((filePath+fileName).c_str()))
         {
             fileName = "fiberfox_motion_";
             fileName += boost::lexical_cast<std::string>(c);
             fileName += ".log";
             c++;
         }
 
         m_Logfile.open((filePath+fileName).c_str());
         m_Logfile << "0 rotation: 0,0,0; translation: 0,0,0\n";
 
         if (m_Parameters.m_SignalGen.m_DoRandomizeMotion)
         {
             m_StatusText += "Adding random motion artifacts:\n";
             m_StatusText += "Maximum rotation: +/-" + boost::lexical_cast<std::string>(m_Parameters.m_SignalGen.m_Rotation) + "°\n";
             m_StatusText += "Maximum translation: +/-" + boost::lexical_cast<std::string>(m_Parameters.m_SignalGen.m_Translation) + "mm\n";
         }
         else
         {
             m_StatusText += "Adding linear motion artifacts:\n";
             m_StatusText += "Maximum rotation: " + boost::lexical_cast<std::string>(m_Parameters.m_SignalGen.m_Rotation) + "°\n";
             m_StatusText += "Maximum translation: " + boost::lexical_cast<std::string>(m_Parameters.m_SignalGen.m_Translation) + "mm\n";
         }
         m_StatusText += "Motion logfile: " + (filePath+fileName) + "\n";
         MITK_INFO << "Adding motion artifacts";
         MITK_INFO << "Maximum rotation: " << m_Parameters.m_SignalGen.m_Rotation;
         MITK_INFO << "Maxmimum translation: " << m_Parameters.m_SignalGen.m_Translation;
     }
     maxVolume = 0;
 
     m_StatusText += "\n"+this->GetTime()+" > Generating " + boost::lexical_cast<std::string>(numFiberCompartments+numNonFiberCompartments) + "-compartment diffusion-weighted signal.\n";
     MITK_INFO << "Generating " << numFiberCompartments+numNonFiberCompartments << "-compartment diffusion-weighted signal.";
     int numFibers = m_FiberBundle->GetNumFibers();
     boost::progress_display disp(numFibers*m_Parameters.m_SignalGen.GetNumVolumes());
 
 
     // get transform for motion artifacts
     m_FiberBundleTransformed = m_FiberBundleWorkingCopy;
     m_Rotation = m_Parameters.m_SignalGen.m_Rotation/m_Parameters.m_SignalGen.GetNumVolumes();
     m_Translation = m_Parameters.m_SignalGen.m_Translation/m_Parameters.m_SignalGen.GetNumVolumes();
 
     // creat image to hold transformed mask (motion artifact)
     m_MaskImage = ItkUcharImgType::New();
     itk::ImageDuplicator<ItkUcharImgType>::Pointer duplicator = itk::ImageDuplicator<ItkUcharImgType>::New();
     duplicator->SetInputImage(m_Parameters.m_SignalGen.m_MaskImage);
     duplicator->Update();
     m_MaskImage = duplicator->GetOutput();
 
     // second upsampling needed for motion artifacts
     ImageRegion<3>      upsampledImageRegion = m_UpsampledImageRegion;
     DoubleVectorType    upsampledSpacing = m_UpsampledSpacing;
     upsampledSpacing[0] /= 4;
     upsampledSpacing[1] /= 4;
     upsampledSpacing[2] /= 4;
     upsampledImageRegion.SetSize(0, m_UpsampledImageRegion.GetSize()[0]*4);
     upsampledImageRegion.SetSize(1, m_UpsampledImageRegion.GetSize()[1]*4);
     upsampledImageRegion.SetSize(2, m_UpsampledImageRegion.GetSize()[2]*4);
     itk::Point<double,3> upsampledOrigin = m_UpsampledOrigin;
     upsampledOrigin[0] -= m_UpsampledSpacing[0]/2; upsampledOrigin[0] += upsampledSpacing[0]/2;
     upsampledOrigin[1] -= m_UpsampledSpacing[1]/2; upsampledOrigin[1] += upsampledSpacing[1]/2;
     upsampledOrigin[2] -= m_UpsampledSpacing[2]/2; upsampledOrigin[2] += upsampledSpacing[2]/2;
     m_UpsampledMaskImage = ItkUcharImgType::New();
     itk::ResampleImageFilter<ItkUcharImgType, ItkUcharImgType>::Pointer upsampler = itk::ResampleImageFilter<ItkUcharImgType, ItkUcharImgType>::New();
     upsampler->SetInput(m_Parameters.m_SignalGen.m_MaskImage);
     upsampler->SetOutputParametersFromImage(m_Parameters.m_SignalGen.m_MaskImage);
     upsampler->SetSize(upsampledImageRegion.GetSize());
     upsampler->SetOutputSpacing(upsampledSpacing);
     upsampler->SetOutputOrigin(upsampledOrigin);
     itk::NearestNeighborInterpolateImageFunction<ItkUcharImgType, double>::Pointer nn_interpolator
             = itk::NearestNeighborInterpolateImageFunction<ItkUcharImgType, double>::New();
     upsampler->SetInterpolator(nn_interpolator);
     upsampler->Update();
     m_UpsampledMaskImage = upsampler->GetOutput();
 
     unsigned long lastTick = 0;
     int signalModelSeed = m_RandGen->GetIntegerVariate();
     switch (m_Parameters.m_SignalGen.m_DiffusionDirectionMode)
     {
     case(SignalGenerationParameters::FIBER_TANGENT_DIRECTIONS):   // use fiber tangent directions to determine diffusion direction
     {
         m_StatusText += "0%   10   20   30   40   50   60   70   80   90   100%\n";
         m_StatusText += "|----|----|----|----|----|----|----|----|----|----|\n*";
 
         for (unsigned int g=0; g<m_Parameters.m_SignalGen.GetNumVolumes(); g++)
         {
             // Set signal model random generator seeds to get same configuration in each voxel
             for (int i=0; i<m_Parameters.m_FiberModelList.size(); i++)
                 m_Parameters.m_FiberModelList.at(i)->SetSeed(signalModelSeed);
             for (int i=0; i<m_Parameters.m_NonFiberModelList.size(); i++)
                 m_Parameters.m_NonFiberModelList.at(i)->SetSeed(signalModelSeed);
 
             ItkDoubleImgType::Pointer intraAxonalVolumeImage = ItkDoubleImgType::New();
             intraAxonalVolumeImage->SetSpacing( m_UpsampledSpacing );
             intraAxonalVolumeImage->SetOrigin( m_UpsampledOrigin );
             intraAxonalVolumeImage->SetDirection( m_Parameters.m_SignalGen.m_ImageDirection );
             intraAxonalVolumeImage->SetLargestPossibleRegion( m_UpsampledImageRegion );
             intraAxonalVolumeImage->SetBufferedRegion( m_UpsampledImageRegion );
             intraAxonalVolumeImage->SetRequestedRegion( m_UpsampledImageRegion );
             intraAxonalVolumeImage->Allocate();
             intraAxonalVolumeImage->FillBuffer(0);
 
             vtkPolyData* fiberPolyData = m_FiberBundleTransformed->GetFiberPolyData();
 
             // generate fiber signal (if there are any fiber models present)
             if (!m_Parameters.m_FiberModelList.empty())
                 for( int i=0; i<numFibers; i++ )
                 {
                     vtkCell* cell = fiberPolyData->GetCell(i);
                     int numPoints = cell->GetNumberOfPoints();
                     vtkPoints* points = cell->GetPoints();
 
                     if (numPoints<2)
                         continue;
 
                     for( int j=0; j<numPoints; j++)
                     {
                         if (this->GetAbortGenerateData())
                         {
                             m_StatusText += "\n"+this->GetTime()+" > Simulation aborted\n";
                             return;
                         }
 
                         double* temp = points->GetPoint(j);
                         itk::Point<float, 3> vertex = GetItkPoint(temp);
                         itk::Vector<double> v = GetItkVector(temp);
 
                         itk::Vector<double, 3> dir(3);
                         if (j<numPoints-1)
                             dir = GetItkVector(points->GetPoint(j+1))-v;
                         else
                             dir = v-GetItkVector(points->GetPoint(j-1));
 
                         if (dir.GetSquaredNorm()<0.0001 || dir[0]!=dir[0] || dir[1]!=dir[1] || dir[2]!=dir[2])
                             continue;
 
                         itk::Index<3> idx;
                         itk::ContinuousIndex<float, 3> contIndex;
                         m_MaskImage->TransformPhysicalPointToIndex(vertex, idx);
                         m_MaskImage->TransformPhysicalPointToContinuousIndex(vertex, contIndex);
 
                         if (!m_MaskImage->GetLargestPossibleRegion().IsInside(idx) || m_MaskImage->GetPixel(idx)<=0)
                             continue;
 
                         // generate signal for each fiber compartment
                         for (int k=0; k<numFiberCompartments; k++)
                         {
                             m_Parameters.m_FiberModelList[k]->SetFiberDirection(dir);
                             DoubleDwiType::PixelType pix = m_CompartmentImages.at(k)->GetPixel(idx);
                             pix[g] += segmentVolume*m_Parameters.m_FiberModelList[k]->SimulateMeasurement(g);
 
                             m_CompartmentImages.at(k)->SetPixel(idx, pix);
                         }
 
                         // update fiber volume image
                         double vol = intraAxonalVolumeImage->GetPixel(idx) + segmentVolume;
                         intraAxonalVolumeImage->SetPixel(idx, vol);
                         if (g==0 && vol>maxVolume)
                             maxVolume = vol;
                     }
 
                     // progress report
                     ++disp;
                     unsigned long newTick = 50*disp.count()/disp.expected_count();
                     for (unsigned int tick = 0; tick<(newTick-lastTick); tick++)
                         m_StatusText += "*";
                     lastTick = newTick;
                 }
 
             // generate non-fiber signal
             ImageRegionIterator<ItkUcharImgType> it3(m_MaskImage, m_MaskImage->GetLargestPossibleRegion());
             double fact = 1;
             if (m_Parameters.m_SignalGen.m_AxonRadius<0.0001 || maxVolume>m_VoxelVolume)
                 fact = m_VoxelVolume/maxVolume;
             while(!it3.IsAtEnd())
             {
                 if (it3.Get()>0)
                 {
                     DoubleDwiType::IndexType index = it3.GetIndex();
 
                     // adjust intra-axonal signal to abtain an only-fiber voxel
                     if (fabs(fact-1.0)>0.0001)
                         for (int i=0; i<numFiberCompartments; i++)
                         {
                             DoubleDwiType::PixelType pix = m_CompartmentImages.at(i)->GetPixel(index);
                             pix[g] *= fact;
                             m_CompartmentImages.at(i)->SetPixel(index, pix);
                         }
 
                     // simulate other compartments
                     SimulateNonFiberSignal(index, intraAxonalVolumeImage->GetPixel(index)*fact, g);
                 }
                 ++it3;
             }
 
             // move fibers
             SimulateMotion(g);
         }
         break;
     }
     case (SignalGenerationParameters::MAIN_FIBER_DIRECTIONS): // use main fiber directions to determine voxel-wise diffusion directions
     {
         typedef itk::Image< itk::Vector< float, 3>, 3 >                                 ItkDirectionImage3DType;
         typedef itk::VectorContainer< unsigned int, ItkDirectionImage3DType::Pointer >  ItkDirectionImageContainerType;
 
         // calculate main fiber directions
         itk::TractsToVectorImageFilter<float>::Pointer fOdfFilter = itk::TractsToVectorImageFilter<float>::New();
         fOdfFilter->SetFiberBundle(m_FiberBundleTransformed);
         fOdfFilter->SetMaskImage(m_MaskImage);
         fOdfFilter->SetAngularThreshold(cos(m_Parameters.m_SignalGen.m_FiberSeparationThreshold*M_PI/180.0));
         fOdfFilter->SetNormalizeVectors(false);
         fOdfFilter->SetUseWorkingCopy(true);
         fOdfFilter->SetSizeThreshold(0);
         fOdfFilter->SetMaxNumDirections(3);
         fOdfFilter->Update();
         ItkDirectionImageContainerType::Pointer directionImageContainer = fOdfFilter->GetDirectionImageContainer();
 
         // allocate image storing intra-axonal volume fraction information
         ItkDoubleImgType::Pointer intraAxonalVolumeImage = ItkDoubleImgType::New();
         intraAxonalVolumeImage->SetSpacing( m_UpsampledSpacing );
         intraAxonalVolumeImage->SetOrigin( m_UpsampledOrigin );
         intraAxonalVolumeImage->SetDirection( m_Parameters.m_SignalGen.m_ImageDirection );
         intraAxonalVolumeImage->SetLargestPossibleRegion( m_UpsampledImageRegion );
         intraAxonalVolumeImage->SetBufferedRegion( m_UpsampledImageRegion );
         intraAxonalVolumeImage->SetRequestedRegion( m_UpsampledImageRegion );
         intraAxonalVolumeImage->Allocate();
         intraAxonalVolumeImage->FillBuffer(0);
 
         // determine intra-axonal volume fraction using the tract density
         itk::TractDensityImageFilter< ItkDoubleImgType >::Pointer tdiFilter = itk::TractDensityImageFilter< ItkDoubleImgType >::New();
         tdiFilter->SetFiberBundle(m_FiberBundleTransformed);
         tdiFilter->SetBinaryOutput(false);
         tdiFilter->SetOutputAbsoluteValues(false);
         tdiFilter->SetInputImage(intraAxonalVolumeImage);
         tdiFilter->SetUseImageGeometry(true);
         tdiFilter->Update();
         intraAxonalVolumeImage = tdiFilter->GetOutput();
 
         m_StatusText += "0%   10   20   30   40   50   60   70   80   90   100%\n";
         m_StatusText += "|----|----|----|----|----|----|----|----|----|----|\n*";
         boost::progress_display disp(m_MaskImage->GetLargestPossibleRegion().GetNumberOfPixels()*m_Parameters.m_SignalGen.GetNumVolumes());
 
         for (unsigned int g=0; g<m_Parameters.m_SignalGen.GetNumVolumes(); g++)
         {
             // Set signal model random generator seeds to get same configuration in each voxel
             for (int i=0; i<m_Parameters.m_FiberModelList.size(); i++)
                 m_Parameters.m_FiberModelList.at(i)->SetSeed(signalModelSeed);
             for (int i=0; i<m_Parameters.m_NonFiberModelList.size(); i++)
                 m_Parameters.m_NonFiberModelList.at(i)->SetSeed(signalModelSeed);
 
             if (m_Parameters.m_SignalGen.m_DoAddMotion && g>0)  // if fibers have moved we need a new TDI and new directions
             {
                 fOdfFilter->SetFiberBundle(m_FiberBundleTransformed);
                 fOdfFilter->SetMaskImage(m_MaskImage);
                 fOdfFilter->Update();
                 directionImageContainer = fOdfFilter->GetDirectionImageContainer();
 
                 tdiFilter->SetFiberBundle(m_FiberBundleTransformed);
                 tdiFilter->Update();
                 intraAxonalVolumeImage = tdiFilter->GetOutput();
             }
 
             ImageRegionIterator< ItkUcharImgType > it(m_MaskImage, m_MaskImage->GetLargestPossibleRegion());
             while(!it.IsAtEnd())
             {
                 ++disp;
                 unsigned long newTick = 50*disp.count()/disp.expected_count();
                 for (unsigned int tick = 0; tick<(newTick-lastTick); tick++)
                     m_StatusText += "*";
                 lastTick = newTick;
 
                 if (this->GetAbortGenerateData())
                 {
                     m_StatusText += "\n"+this->GetTime()+" > Simulation aborted\n";
                     return;
                 }
 
                 if (it.Get()>0)
                 {
                     // generate fiber signal
                     for (int c=0; c<m_Parameters.m_FiberModelList.size(); c++)
                     {
                         int count = 0;
                         DoubleDwiType::PixelType pix = m_CompartmentImages.at(c)->GetPixel(it.GetIndex());
                         for (unsigned int i=0; i<directionImageContainer->Size(); i++)
                         {
                             itk::Vector< double, 3> dir;
                             dir.CastFrom(directionImageContainer->GetElement(i)->GetPixel(it.GetIndex()));
                             double norm = dir.GetNorm();
                             if (norm>0.0001)
                             {
                                 m_Parameters.m_FiberModelList.at(c)->SetFiberDirection(dir);
                                 pix[g] += m_Parameters.m_FiberModelList.at(c)->SimulateMeasurement(g)*norm;
                                 count++;
                             }
                         }
                         if (count>0)
                             pix[g] /= count;
                         pix[g] *= intraAxonalVolumeImage->GetPixel(it.GetIndex())*m_VoxelVolume;
                         m_CompartmentImages.at(c)->SetPixel(it.GetIndex(), pix);
                     }
 
                     // simulate other compartments
                     SimulateNonFiberSignal(it.GetIndex(), intraAxonalVolumeImage->GetPixel(it.GetIndex())*m_VoxelVolume, g);
                 }
                 ++it;
             }
 
             SimulateMotion(g);
         }
 
         itk::ImageFileWriter< ItkUcharImgType >::Pointer wr = itk::ImageFileWriter< ItkUcharImgType >::New();
         wr->SetInput(fOdfFilter->GetNumDirectionsImage());
         wr->SetFileName(mitk::IOUtil::GetTempPath()+"/NumDirections_MainFiberDirections.nrrd");
         wr->Update();
         break;
     }
     case (SignalGenerationParameters::RANDOM_DIRECTIONS):
     {
         ItkUcharImgType::Pointer numDirectionsImage = ItkUcharImgType::New();
         numDirectionsImage->SetSpacing( m_UpsampledSpacing );
         numDirectionsImage->SetOrigin( m_UpsampledOrigin );
         numDirectionsImage->SetDirection( m_Parameters.m_SignalGen.m_ImageDirection );
         numDirectionsImage->SetLargestPossibleRegion( m_UpsampledImageRegion );
         numDirectionsImage->SetBufferedRegion( m_UpsampledImageRegion );
         numDirectionsImage->SetRequestedRegion( m_UpsampledImageRegion );
         numDirectionsImage->Allocate();
         numDirectionsImage->FillBuffer(0);
         double sepAngle = cos(m_Parameters.m_SignalGen.m_FiberSeparationThreshold*M_PI/180.0);
 
         m_StatusText += "0%   10   20   30   40   50   60   70   80   90   100%\n";
         m_StatusText += "|----|----|----|----|----|----|----|----|----|----|\n*";
         boost::progress_display disp(m_MaskImage->GetLargestPossibleRegion().GetNumberOfPixels());
         ImageRegionIterator<ItkUcharImgType> it(m_MaskImage, m_MaskImage->GetLargestPossibleRegion());
         while(!it.IsAtEnd())
         {
             ++disp;
             unsigned long newTick = 50*disp.count()/disp.expected_count();
             for (unsigned int tick = 0; tick<(newTick-lastTick); tick++)
                 m_StatusText += "*";
             lastTick = newTick;
 
             if (this->GetAbortGenerateData())
             {
                 m_StatusText += "\n"+this->GetTime()+" > Simulation aborted\n";
                 return;
             }
 
             if (it.Get()>0)
             {
                 int numFibs = m_RandGen->GetIntegerVariate(2)+1;
                 DoubleDwiType::PixelType pix = m_CompartmentImages.at(0)->GetPixel(it.GetIndex());
                 double volume = m_RandGen->GetVariateWithClosedRange(0.3);
 
                 //                double sum = 0;
                 std::vector< double > fractions;
                 for (int i=0; i<numFibs; i++)
                 {
                     //                    fractions.push_back(1);
                     fractions.push_back(0.5+m_RandGen->GetVariateWithClosedRange(0.5));
                     //                    sum += fractions.at(i);
                 }
                 //                for (int i=0; i<numFibs; i++)
                 //                    fractions[i] /= sum;
 
                 std::vector< itk::Vector<double, 3> > directions;
                 for (int i=0; i<numFibs; i++)
                 {
                     DoubleVectorType fib;
                     fib[0] = m_RandGen->GetVariateWithClosedRange(2)-1.0;
                     fib[1] = m_RandGen->GetVariateWithClosedRange(2)-1.0;
                     fib[2] = m_RandGen->GetVariateWithClosedRange(2)-1.0;
                     fib.Normalize();
 
                     double min = 0;
                     for (unsigned int d=0; d<directions.size(); d++)
                     {
                         double angle = fabs(fib*directions[d]);
                         if (angle>min)
                             min = angle;
                     }
                     if (min<sepAngle)
                     {
                         m_Parameters.m_FiberModelList.at(0)->SetFiberDirection(fib);
                         pix += m_Parameters.m_FiberModelList.at(0)->SimulateMeasurement()*fractions[i];
                         directions.push_back(fib);
                     }
                     else
                         i--;
                 }
                 pix *= (1-volume);
                 m_CompartmentImages.at(0)->SetPixel(it.GetIndex(), pix);
 
                 // CSF/GM
                 {
                     pix += volume*m_Parameters.m_NonFiberModelList.at(0)->SimulateMeasurement();
                 }
 
                 numDirectionsImage->SetPixel(it.GetIndex(), numFibs);
             }
             ++it;
         }
 
         itk::ImageFileWriter< ItkUcharImgType >::Pointer wr = itk::ImageFileWriter< ItkUcharImgType >::New();
         wr->SetInput(numDirectionsImage);
         wr->SetFileName(mitk::IOUtil::GetTempPath()+"/NumDirections_RandomDirections.nrrd");
         wr->Update();
     }
     }
 
     if (m_Logfile.is_open())
     {
         m_Logfile << "DONE";
         m_Logfile.close();
     }
     m_StatusText += "\n\n";
     if (this->GetAbortGenerateData())
     {
         m_StatusText += "\n"+this->GetTime()+" > Simulation aborted\n";
         return;
     }
 
     DoubleDwiType::Pointer doubleOutImage;
     if ( m_Parameters.m_SignalGen.m_SimulateKspaceAcquisition ) // do k-space stuff
     {
         m_StatusText += this->GetTime()+" > Adjusting complex signal\n";
         MITK_INFO << "Adjusting complex signal:";
 
         if (m_Parameters.m_SignalGen.m_DoSimulateRelaxation)
             m_StatusText += "Simulating signal relaxation\n";
         if (m_Parameters.m_SignalGen.m_FrequencyMap.IsNotNull())
             m_StatusText += "Simulating distortions\n";
         if (m_Parameters.m_SignalGen.m_DoAddGibbsRinging)
             m_StatusText += "Simulating ringing artifacts\n";
         if (m_Parameters.m_SignalGen.m_EddyStrength>0)
             m_StatusText += "Simulating eddy currents\n";
         if (m_Parameters.m_SignalGen.m_Spikes>0)
             m_StatusText += "Simulating spikes\n";
         if (m_Parameters.m_SignalGen.m_CroppingFactor<1.0)
             m_StatusText += "Simulating aliasing artifacts\n";
         if (m_Parameters.m_SignalGen.m_KspaceLineOffset>0)
             m_StatusText += "Simulating ghosts\n";
 
         doubleOutImage = DoKspaceStuff(m_CompartmentImages);
         m_Parameters.m_SignalGen.m_SignalScale = 1; // already scaled in DoKspaceStuff
     }
     else    // don't do k-space stuff, just sum compartments
     {
         m_StatusText += this->GetTime()+" > Summing compartments\n";
         MITK_INFO << "Summing compartments";
         doubleOutImage = m_CompartmentImages.at(0);
 
         for (unsigned int i=1; i<m_CompartmentImages.size(); i++)
         {
             itk::AddImageFilter< DoubleDwiType, DoubleDwiType, DoubleDwiType>::Pointer adder = itk::AddImageFilter< DoubleDwiType, DoubleDwiType, DoubleDwiType>::New();
             adder->SetInput1(doubleOutImage);
             adder->SetInput2(m_CompartmentImages.at(i));
             adder->Update();
             doubleOutImage = adder->GetOutput();
         }
     }
     if (this->GetAbortGenerateData())
     {
         m_StatusText += "\n"+this->GetTime()+" > Simulation aborted\n";
         return;
     }
 
     m_StatusText += this->GetTime()+" > Finalizing image\n";
     MITK_INFO << "Finalizing image";
     if (m_Parameters.m_SignalGen.m_SignalScale>1)
         m_StatusText += " Scaling signal\n";
     if (m_Parameters.m_NoiseModel!=NULL)
         m_StatusText += " Adding noise\n";
     unsigned int window = 0;
     unsigned int min = itk::NumericTraits<unsigned int>::max();
     ImageRegionIterator<OutputImageType> it4 (outImage, outImage->GetLargestPossibleRegion());
     DoubleDwiType::PixelType signal; signal.SetSize(m_Parameters.m_SignalGen.GetNumVolumes());
     boost::progress_display disp2(outImage->GetLargestPossibleRegion().GetNumberOfPixels());
 
     m_StatusText += "0%   10   20   30   40   50   60   70   80   90   100%\n";
     m_StatusText += "|----|----|----|----|----|----|----|----|----|----|\n*";
     lastTick = 0;
 
     while(!it4.IsAtEnd())
     {
         if (this->GetAbortGenerateData())
         {
             m_StatusText += "\n"+this->GetTime()+" > Simulation aborted\n";
             return;
         }
 
         ++disp2;
         unsigned long newTick = 50*disp2.count()/disp2.expected_count();
         for (unsigned long tick = 0; tick<(newTick-lastTick); tick++)
             m_StatusText += "*";
         lastTick = newTick;
 
         typename OutputImageType::IndexType index = it4.GetIndex();
         signal = doubleOutImage->GetPixel(index)*m_Parameters.m_SignalGen.m_SignalScale;
 
         if (m_Parameters.m_NoiseModel!=NULL)
             m_Parameters.m_NoiseModel->AddNoise(signal);
 
         for (unsigned int i=0; i<signal.Size(); i++)
         {
             if (signal[i]>0)
                 signal[i] = floor(signal[i]+0.5);
             else
                 signal[i] = ceil(signal[i]-0.5);
 
             if ( (!m_Parameters.m_SignalGen.IsBaselineIndex(i) || signal.Size()==1) && signal[i]>window)
                 window = signal[i];
             if ( (!m_Parameters.m_SignalGen.IsBaselineIndex(i) || signal.Size()==1) && signal[i]<min)
                 min = signal[i];
         }
         it4.Set(signal);
         ++it4;
     }
     window -= min;
     unsigned int level = window/2 + min;
     m_LevelWindow.SetLevelWindow(level, window);
     this->SetNthOutput(0, outImage);
 
     m_StatusText += "\n\n";
     m_StatusText += "Finished simulation\n";
     m_StatusText += "Simulation time: "+GetTime();
     m_TimeProbe.Stop();
 }
 
 template< class PixelType >
 void TractsToDWIImageFilter< PixelType >::SimulateMotion(int g)
 {
     if (m_Parameters.m_SignalGen.m_DoAddMotion && g<m_Parameters.m_SignalGen.GetNumVolumes()-1)
     {
         if (m_Parameters.m_SignalGen.m_DoRandomizeMotion)
         {
             m_FiberBundleTransformed = m_FiberBundleWorkingCopy->GetDeepCopy();
             m_Rotation[0] = m_RandGen->GetVariateWithClosedRange(m_Parameters.m_SignalGen.m_Rotation[0]*2)-m_Parameters.m_SignalGen.m_Rotation[0];
             m_Rotation[1] = m_RandGen->GetVariateWithClosedRange(m_Parameters.m_SignalGen.m_Rotation[1]*2)-m_Parameters.m_SignalGen.m_Rotation[1];
             m_Rotation[2] = m_RandGen->GetVariateWithClosedRange(m_Parameters.m_SignalGen.m_Rotation[2]*2)-m_Parameters.m_SignalGen.m_Rotation[2];
             m_Translation[0] = m_RandGen->GetVariateWithClosedRange(m_Parameters.m_SignalGen.m_Translation[0]*2)-m_Parameters.m_SignalGen.m_Translation[0];
             m_Translation[1] = m_RandGen->GetVariateWithClosedRange(m_Parameters.m_SignalGen.m_Translation[1]*2)-m_Parameters.m_SignalGen.m_Translation[1];
             m_Translation[2] = m_RandGen->GetVariateWithClosedRange(m_Parameters.m_SignalGen.m_Translation[2]*2)-m_Parameters.m_SignalGen.m_Translation[2];
         }
 
         // rotate mask image
         if (m_MaskImageSet)
         {
             ImageRegionIterator<ItkUcharImgType> maskIt(m_UpsampledMaskImage, m_UpsampledMaskImage->GetLargestPossibleRegion());
             m_MaskImage->FillBuffer(0);
 
             while(!maskIt.IsAtEnd())
             {
                 if (maskIt.Get()<=0)
                 {
                     ++maskIt;
                     continue;
                 }
 
                 DoubleDwiType::IndexType index = maskIt.GetIndex();
                 itk::Point<double, 3> point;
                 m_UpsampledMaskImage->TransformIndexToPhysicalPoint(index, point);
                 if (m_Parameters.m_SignalGen.m_DoRandomizeMotion)
                     point = m_FiberBundleWorkingCopy->TransformPoint(point.GetVnlVector(), m_Rotation[0],m_Rotation[1],m_Rotation[2],m_Translation[0],m_Translation[1],m_Translation[2]);
                 else
                     point = m_FiberBundleWorkingCopy->TransformPoint(point.GetVnlVector(), m_Rotation[0]*(g+1),m_Rotation[1]*(g+1),m_Rotation[2]*(g+1),m_Translation[0]*(g+1),m_Translation[1]*(g+1),m_Translation[2]*(g+1));
 
                 m_MaskImage->TransformPhysicalPointToIndex(point, index);
                 if (m_MaskImage->GetLargestPossibleRegion().IsInside(index))
                     m_MaskImage->SetPixel(index,100);
                 ++maskIt;
             }
         }
 
         // rotate fibers
         if (m_Logfile.is_open())
         {
             m_Logfile << g+1 << " rotation: " << m_Rotation[0] << "," << m_Rotation[1] << "," << m_Rotation[2] << ";";
             m_Logfile << " translation: " << m_Translation[0] << "," << m_Translation[1] << "," << m_Translation[2] << "\n";
         }
         m_FiberBundleTransformed->TransformFibers(m_Rotation[0],m_Rotation[1],m_Rotation[2],m_Translation[0],m_Translation[1],m_Translation[2]);
     }
 }
 
 template< class PixelType >
 void TractsToDWIImageFilter< PixelType >::SimulateNonFiberSignal(ItkUcharImgType::IndexType index, double intraAxonalVolume, int g)
 {
     int numFiberCompartments = m_Parameters.m_FiberModelList.size();
     int numNonFiberCompartments = m_Parameters.m_NonFiberModelList.size();
 
     if (intraAxonalVolume>0.0001 && m_Parameters.m_SignalGen.m_DoDisablePartialVolume)  // only fiber in voxel
     {
         DoubleDwiType::PixelType pix = m_CompartmentImages.at(0)->GetPixel(index);
         if (g>=0)
             pix[g] *= m_VoxelVolume/intraAxonalVolume;
         else
             pix *= m_VoxelVolume/intraAxonalVolume;
         m_CompartmentImages.at(0)->SetPixel(index, pix);
         m_VolumeFractions.at(0)->SetPixel(index, 1);
         for (int i=1; i<numFiberCompartments; i++)
         {
             DoubleDwiType::PixelType pix = m_CompartmentImages.at(i)->GetPixel(index);
             if (g>=0)
                 pix[g] = 0.0;
             else
                 pix.Fill(0.0);
             m_CompartmentImages.at(i)->SetPixel(index, pix);
         }
     }
     else
     {
         m_VolumeFractions.at(0)->SetPixel(index, intraAxonalVolume/m_VoxelVolume);
 
         itk::Point<double, 3> point;
         m_MaskImage->TransformIndexToPhysicalPoint(index, point);
         if (m_Parameters.m_SignalGen.m_DoAddMotion)
         {
             if (m_Parameters.m_SignalGen.m_DoRandomizeMotion && g>0)
                 point = m_FiberBundleWorkingCopy->TransformPoint(point.GetVnlVector(), -m_Rotation[0],-m_Rotation[1],-m_Rotation[2],-m_Translation[0],-m_Translation[1],-m_Translation[2]);
             else if (g>=0)
                 point = m_FiberBundleWorkingCopy->TransformPoint(point.GetVnlVector(), -m_Rotation[0]*g,-m_Rotation[1]*g,-m_Rotation[2]*g,-m_Translation[0]*g,-m_Translation[1]*g,-m_Translation[2]*g);
         }
 
         if (m_Parameters.m_SignalGen.m_DoDisablePartialVolume)
         {
             int maxVolumeIndex = 0;
             double maxWeight = 0;
             for (int i=0; i<numNonFiberCompartments; i++)
             {
                 double weight = 0;
                 if (numNonFiberCompartments>1)
                 {
                     DoubleDwiType::IndexType newIndex;
                     m_Parameters.m_NonFiberModelList[i]->GetVolumeFractionImage()->TransformPhysicalPointToIndex(point, newIndex);
                     if (!m_Parameters.m_NonFiberModelList[i]->GetVolumeFractionImage()->GetLargestPossibleRegion().IsInside(newIndex))
                         continue;
                     weight = m_Parameters.m_NonFiberModelList[i]->GetVolumeFractionImage()->GetPixel(newIndex);
                 }
 
                 if (weight>maxWeight)
                 {
                     maxWeight = weight;
                     maxVolumeIndex = i;
                 }
             }
             DoubleDwiType::Pointer doubleDwi = m_CompartmentImages.at(maxVolumeIndex+numFiberCompartments);
             DoubleDwiType::PixelType pix = doubleDwi->GetPixel(index);
 
             if (g>=0)
                 pix[g] += m_Parameters.m_NonFiberModelList[maxVolumeIndex]->SimulateMeasurement(g);
             else
                 pix += m_Parameters.m_NonFiberModelList[maxVolumeIndex]->SimulateMeasurement();
             doubleDwi->SetPixel(index, pix);
             m_VolumeFractions.at(maxVolumeIndex+numFiberCompartments)->SetPixel(index, 1);
         }
         else
         {
             double extraAxonalVolume = m_VoxelVolume-intraAxonalVolume;    // non-fiber volume
             double interAxonalVolume = 0;
             if (numFiberCompartments>1)
                 interAxonalVolume = extraAxonalVolume * intraAxonalVolume/m_VoxelVolume;   // inter-axonal fraction of non fiber compartment scales linearly with f
             double other = extraAxonalVolume - interAxonalVolume;        // rest of compartment
             double singleinter = interAxonalVolume/(numFiberCompartments-1);
 
             // adjust non-fiber and intra-axonal signal
             for (int i=1; i<numFiberCompartments; i++)
             {
                 DoubleDwiType::PixelType pix = m_CompartmentImages.at(i)->GetPixel(index);
                 if (intraAxonalVolume>0)    // remove scaling by intra-axonal volume from inter-axonal compartment
                 {
                     if (g>=0)
                         pix[g] /= intraAxonalVolume;
                     else
                         pix /= intraAxonalVolume;
                 }
                 if (g>=0)
                     pix[g] *= singleinter;
                 else
                     pix *= singleinter;
                 m_CompartmentImages.at(i)->SetPixel(index, pix);
                 m_VolumeFractions.at(i)->SetPixel(index, singleinter/m_VoxelVolume);
             }
 
             for (int i=0; i<numNonFiberCompartments; i++)
             {
                 double weight = 1;
                 if (numNonFiberCompartments>1)
                 {
                     DoubleDwiType::IndexType newIndex;
                     m_Parameters.m_NonFiberModelList[i]->GetVolumeFractionImage()->TransformPhysicalPointToIndex(point, newIndex);
                     if (!m_Parameters.m_NonFiberModelList[i]->GetVolumeFractionImage()->GetLargestPossibleRegion().IsInside(newIndex))
                         continue;
                     weight = m_Parameters.m_NonFiberModelList[i]->GetVolumeFractionImage()->GetPixel(newIndex);
                 }
 
                 DoubleDwiType::Pointer doubleDwi = m_CompartmentImages.at(i+numFiberCompartments);
                 DoubleDwiType::PixelType pix = doubleDwi->GetPixel(index);
 
                 if (g>=0)
                     pix[g] += m_Parameters.m_NonFiberModelList[i]->SimulateMeasurement(g)*other*weight;
                 else
                     pix += m_Parameters.m_NonFiberModelList[i]->SimulateMeasurement()*other*weight;
                 doubleDwi->SetPixel(index, pix);
                 m_VolumeFractions.at(i+numFiberCompartments)->SetPixel(index, other/m_VoxelVolume*weight);
             }
         }
     }
 }
 
 template< class PixelType >
 itk::Point<float, 3> TractsToDWIImageFilter< PixelType >::GetItkPoint(double point[3])
 {
     itk::Point<float, 3> itkPoint;
     itkPoint[0] = point[0];
     itkPoint[1] = point[1];
     itkPoint[2] = point[2];
     return itkPoint;
 }
 
 template< class PixelType >
 itk::Vector<double, 3> TractsToDWIImageFilter< PixelType >::GetItkVector(double point[3])
 {
     itk::Vector<double, 3> itkVector;
     itkVector[0] = point[0];
     itkVector[1] = point[1];
     itkVector[2] = point[2];
     return itkVector;
 }
 
 template< class PixelType >
 vnl_vector_fixed<double, 3> TractsToDWIImageFilter< PixelType >::GetVnlVector(double point[3])
 {
     vnl_vector_fixed<double, 3> vnlVector;
     vnlVector[0] = point[0];
     vnlVector[1] = point[1];
     vnlVector[2] = point[2];
     return vnlVector;
 }
 
 template< class PixelType >
 vnl_vector_fixed<double, 3> TractsToDWIImageFilter< PixelType >::GetVnlVector(Vector<float,3>& vector)
 {
     vnl_vector_fixed<double, 3> vnlVector;
     vnlVector[0] = vector[0];
     vnlVector[1] = vector[1];
     vnlVector[2] = vector[2];
     return vnlVector;
 }
 
 template< class PixelType >
 double TractsToDWIImageFilter< PixelType >::RoundToNearest(double num) {
     return (num > 0.0) ? floor(num + 0.5) : ceil(num - 0.5);
 }
 
 template< class PixelType >
 std::string TractsToDWIImageFilter< PixelType >::GetTime()
 {
     m_TimeProbe.Stop();
     unsigned long total = RoundToNearest(m_TimeProbe.GetTotal());
     unsigned long hours = total/3600;
     unsigned long minutes = (total%3600)/60;
     unsigned long seconds = total%60;
     std::string out = "";
     out.append(boost::lexical_cast<std::string>(hours));
     out.append(":");
     out.append(boost::lexical_cast<std::string>(minutes));
     out.append(":");
     out.append(boost::lexical_cast<std::string>(seconds));
     m_TimeProbe.Start();
     return out;
 }
 
 }
diff --git a/Modules/DiffusionImaging/FiberTracking/Algorithms/itkTractsToRgbaImageFilter.cpp b/Modules/DiffusionImaging/FiberTracking/Algorithms/itkTractsToRgbaImageFilter.cpp
index acae9e38e8..17cab3799c 100644
--- a/Modules/DiffusionImaging/FiberTracking/Algorithms/itkTractsToRgbaImageFilter.cpp
+++ b/Modules/DiffusionImaging/FiberTracking/Algorithms/itkTractsToRgbaImageFilter.cpp
@@ -1,286 +1,286 @@
 /*===================================================================
 
 The Medical Imaging Interaction Toolkit (MITK)
 
 Copyright (c) German Cancer Research Center,
 Division of Medical and Biological Informatics.
 All rights reserved.
 
 This software is distributed WITHOUT ANY WARRANTY; without
 even the implied warranty of MERCHANTABILITY or FITNESS FOR
 A PARTICULAR PURPOSE.
 
 See LICENSE.txt or http://www.mitk.org for details.
 
 ===================================================================*/
 #include "itkTractsToRgbaImageFilter.h"
 
 // VTK
 #include <vtkPolyLine.h>
 #include <vtkCellArray.h>
 #include <vtkCellData.h>
 
 // misc
 #include <math.h>
 #include <boost/progress.hpp>
 
 namespace itk{
 
   template< class OutputImageType >
   TractsToRgbaImageFilter< OutputImageType >::TractsToRgbaImageFilter()
     : m_UpsamplingFactor(1)
     , m_InputImage(NULL)
     , m_UseImageGeometry(false)
   {
 
   }
 
   template< class OutputImageType >
   TractsToRgbaImageFilter< OutputImageType >::~TractsToRgbaImageFilter()
   {
   }
 
   template< class OutputImageType >
   itk::Point<float, 3> TractsToRgbaImageFilter< OutputImageType >::GetItkPoint(double point[3])
   {
     itk::Point<float, 3> itkPoint;
     itkPoint[0] = point[0];
     itkPoint[1] = point[1];
     itkPoint[2] = point[2];
     return itkPoint;
   }
 
   template< class OutputImageType >
   void TractsToRgbaImageFilter< OutputImageType >::GenerateData()
   {
     if(&typeid(OutPixelType) != &typeid(itk::RGBAPixel<unsigned char>))
       return;
 
     // generate upsampled image
     mitk::BaseGeometry::Pointer geometry = m_FiberBundle->GetGeometry();
     typename OutputImageType::Pointer outImage = this->GetOutput();
 
     // calculate new image parameters
     itk::Vector<double,3> newSpacing;
     mitk::Point3D newOrigin;
     itk::Matrix<double, 3, 3> newDirection;
     ImageRegion<3> upsampledRegion;
     if (m_UseImageGeometry && !m_InputImage.IsNull())
     {
       newSpacing = m_InputImage->GetSpacing()/m_UpsamplingFactor;
       upsampledRegion = m_InputImage->GetLargestPossibleRegion();
       newOrigin = m_InputImage->GetOrigin();
       typename OutputImageType::RegionType::SizeType size = upsampledRegion.GetSize();
       size[0] *= m_UpsamplingFactor;
       size[1] *= m_UpsamplingFactor;
       size[2] *= m_UpsamplingFactor;
       upsampledRegion.SetSize(size);
       newDirection = m_InputImage->GetDirection();
     }
     else
     {
       newSpacing = geometry->GetSpacing()/m_UpsamplingFactor;
       newOrigin = geometry->GetOrigin();
       mitk::Geometry3D::BoundsArrayType bounds = geometry->GetBounds();
       newOrigin[0] += bounds.GetElement(0);
       newOrigin[1] += bounds.GetElement(2);
       newOrigin[2] += bounds.GetElement(4);
 
       for (int i=0; i<3; i++)
         for (int j=0; j<3; j++)
           newDirection[j][i] = geometry->GetMatrixColumn(i)[j];
       upsampledRegion.SetSize(0, geometry->GetExtent(0)*m_UpsamplingFactor);
       upsampledRegion.SetSize(1, geometry->GetExtent(1)*m_UpsamplingFactor);
       upsampledRegion.SetSize(2, geometry->GetExtent(2)*m_UpsamplingFactor);
     }
     typename OutputImageType::RegionType::SizeType upsampledSize = upsampledRegion.GetSize();
 
     // apply new image parameters
     outImage->SetSpacing( newSpacing );
     outImage->SetOrigin( newOrigin );
     outImage->SetDirection( newDirection );
     outImage->SetRegions( upsampledRegion );
     outImage->Allocate();
 
     int w = upsampledSize[0];
     int h = upsampledSize[1];
     int d = upsampledSize[2];
 
     // set/initialize output
     unsigned char* outImageBufferPointer = (unsigned char*)outImage->GetBufferPointer();
     float* buffer = new float[w*h*d*4];
     for (int i=0; i<w*h*d*4; i++)
       buffer[i] = 0;
 
     // resample fiber bundle
     float minSpacing = 1;
     if(newSpacing[0]<newSpacing[1] && newSpacing[0]<newSpacing[2])
         minSpacing = newSpacing[0];
     else if (newSpacing[1] < newSpacing[2])
         minSpacing = newSpacing[1];
     else
         minSpacing = newSpacing[2];
 
     m_FiberBundle = m_FiberBundle->GetDeepCopy();
-    m_FiberBundle->ResampleLinear(minSpacing);
+    m_FiberBundle->ResampleSpline(minSpacing);
 
     vtkSmartPointer<vtkPolyData> fiberPolyData = m_FiberBundle->GetFiberPolyData();
     vtkSmartPointer<vtkCellArray> vLines = fiberPolyData->GetLines();
     vLines->InitTraversal();
 
     int numFibers = m_FiberBundle->GetNumFibers();
     boost::progress_display disp(numFibers);
     for( int i=0; i<numFibers; i++ )
     {
       ++disp;
       vtkIdType   numPoints(0);
       vtkIdType*  points(NULL);
       vLines->GetNextCell ( numPoints, points );
 
       // calc directions (which are used as weights)
       std::list< itk::Point<float, 3> > rgbweights;
       std::list<float> intensities;
 
       for( int j=0; j<numPoints-1; j++)
       {
 
         itk::Point<float, 3> vertex = GetItkPoint(fiberPolyData->GetPoint(points[j]));
         itk::Point<float, 3> vertexPost = GetItkPoint(fiberPolyData->GetPoint(points[j+1]));
 
         itk::Point<float, 3> dir;
         dir[0] = fabs((vertexPost[0] - vertex[0]) * outImage->GetSpacing()[0]);
         dir[1] = fabs((vertexPost[1] - vertex[1]) * outImage->GetSpacing()[1]);
         dir[2] = fabs((vertexPost[2] - vertex[2]) * outImage->GetSpacing()[2]);
 
         rgbweights.push_back(dir);
 
         float intensity = sqrt(dir[0]*dir[0]+dir[1]*dir[1]+dir[2]*dir[2]);
         intensities.push_back(intensity);
 
         // last point gets same as previous one
         if(j==numPoints-2)
         {
           rgbweights.push_back(dir);
           intensities.push_back(intensity);
         }
       }
 
       // fill output image
       for( int j=0; j<numPoints; j++)
       {
         itk::Point<float, 3> vertex = GetItkPoint(fiberPolyData->GetPoint(points[j]));
         itk::Index<3> index;
         itk::ContinuousIndex<float, 3> contIndex;
         outImage->TransformPhysicalPointToIndex(vertex, index);
         outImage->TransformPhysicalPointToContinuousIndex(vertex, contIndex);
 
         float frac_x = contIndex[0] - index[0];
         float frac_y = contIndex[1] - index[1];
         float frac_z = contIndex[2] - index[2];
 
         int px = index[0];
         if (frac_x<0)
         {
           px -= 1;
           frac_x += 1;
         }
 
         int py = index[1];
         if (frac_y<0)
         {
           py -= 1;
           frac_y += 1;
         }
 
         int pz = index[2];
         if (frac_z<0)
         {
           pz -= 1;
           frac_z += 1;
         }
 
         // int coordinates inside image?
         if (px < 0 || px >= w-1)
           continue;
         if (py < 0 || py >= h-1)
           continue;
         if (pz < 0 || pz >= d-1)
           continue;
 
         float scale = 100 * pow((float)m_UpsamplingFactor,3);
         itk::Point<float, 3> rgbweight = rgbweights.front();
         rgbweights.pop_front();
         float intweight = intensities.front();
         intensities.pop_front();
 
         // add to r-channel in output image
         buffer[0+4*( px   + w*(py  + h*pz  ))] += (1-frac_x)*(1-frac_y)*(1-frac_z) * rgbweight[0] * scale;
         buffer[0+4*( px   + w*(py+1+ h*pz  ))] += (1-frac_x)*(  frac_y)*(1-frac_z) * rgbweight[0] * scale;
         buffer[0+4*( px   + w*(py  + h*pz+h))] += (1-frac_x)*(1-frac_y)*(  frac_z) * rgbweight[0] * scale;
         buffer[0+4*( px   + w*(py+1+ h*pz+h))] += (1-frac_x)*(  frac_y)*(  frac_z) * rgbweight[0] * scale;
         buffer[0+4*( px+1 + w*(py  + h*pz  ))] += (  frac_x)*(1-frac_y)*(1-frac_z) * rgbweight[0] * scale;
         buffer[0+4*( px+1 + w*(py  + h*pz+h))] += (  frac_x)*(1-frac_y)*(  frac_z) * rgbweight[0] * scale;
         buffer[0+4*( px+1 + w*(py+1+ h*pz  ))] += (  frac_x)*(  frac_y)*(1-frac_z) * rgbweight[0] * scale;
         buffer[0+4*( px+1 + w*(py+1+ h*pz+h))] += (  frac_x)*(  frac_y)*(  frac_z) * rgbweight[0] * scale;
 
         // add to g-channel in output image
         buffer[1+4*( px   + w*(py  + h*pz  ))] += (1-frac_x)*(1-frac_y)*(1-frac_z) * rgbweight[1] * scale;
         buffer[1+4*( px   + w*(py+1+ h*pz  ))] += (1-frac_x)*(  frac_y)*(1-frac_z) * rgbweight[1] * scale;
         buffer[1+4*( px   + w*(py  + h*pz+h))] += (1-frac_x)*(1-frac_y)*(  frac_z) * rgbweight[1] * scale;
         buffer[1+4*( px   + w*(py+1+ h*pz+h))] += (1-frac_x)*(  frac_y)*(  frac_z) * rgbweight[1] * scale;
         buffer[1+4*( px+1 + w*(py  + h*pz  ))] += (  frac_x)*(1-frac_y)*(1-frac_z) * rgbweight[1] * scale;
         buffer[1+4*( px+1 + w*(py  + h*pz+h))] += (  frac_x)*(1-frac_y)*(  frac_z) * rgbweight[1] * scale;
         buffer[1+4*( px+1 + w*(py+1+ h*pz  ))] += (  frac_x)*(  frac_y)*(1-frac_z) * rgbweight[1] * scale;
         buffer[1+4*( px+1 + w*(py+1+ h*pz+h))] += (  frac_x)*(  frac_y)*(  frac_z) * rgbweight[1] * scale;
 
         // add to b-channel in output image
         buffer[2+4*( px   + w*(py  + h*pz  ))] += (1-frac_x)*(1-frac_y)*(1-frac_z) * rgbweight[2] * scale;
         buffer[2+4*( px   + w*(py+1+ h*pz  ))] += (1-frac_x)*(  frac_y)*(1-frac_z) * rgbweight[2] * scale;
         buffer[2+4*( px   + w*(py  + h*pz+h))] += (1-frac_x)*(1-frac_y)*(  frac_z) * rgbweight[2] * scale;
         buffer[2+4*( px   + w*(py+1+ h*pz+h))] += (1-frac_x)*(  frac_y)*(  frac_z) * rgbweight[2] * scale;
         buffer[2+4*( px+1 + w*(py  + h*pz  ))] += (  frac_x)*(1-frac_y)*(1-frac_z) * rgbweight[2] * scale;
         buffer[2+4*( px+1 + w*(py  + h*pz+h))] += (  frac_x)*(1-frac_y)*(  frac_z) * rgbweight[2] * scale;
         buffer[2+4*( px+1 + w*(py+1+ h*pz  ))] += (  frac_x)*(  frac_y)*(1-frac_z) * rgbweight[2] * scale;
         buffer[2+4*( px+1 + w*(py+1+ h*pz+h))] += (  frac_x)*(  frac_y)*(  frac_z) * rgbweight[2] * scale;
 
         // add to a-channel in output image
         buffer[3+4*( px   + w*(py  + h*pz  ))] += (1-frac_x)*(1-frac_y)*(1-frac_z) * intweight * scale;
         buffer[3+4*( px   + w*(py+1+ h*pz  ))] += (1-frac_x)*(  frac_y)*(1-frac_z) * intweight * scale;
         buffer[3+4*( px   + w*(py  + h*pz+h))] += (1-frac_x)*(1-frac_y)*(  frac_z) * intweight * scale;
         buffer[3+4*( px   + w*(py+1+ h*pz+h))] += (1-frac_x)*(  frac_y)*(  frac_z) * intweight * scale;
         buffer[3+4*( px+1 + w*(py  + h*pz  ))] += (  frac_x)*(1-frac_y)*(1-frac_z) * intweight * scale;
         buffer[3+4*( px+1 + w*(py  + h*pz+h))] += (  frac_x)*(1-frac_y)*(  frac_z) * intweight * scale;
         buffer[3+4*( px+1 + w*(py+1+ h*pz  ))] += (  frac_x)*(  frac_y)*(1-frac_z) * intweight * scale;
         buffer[3+4*( px+1 + w*(py+1+ h*pz+h))] += (  frac_x)*(  frac_y)*(  frac_z) * intweight * scale;
       }
     }
     float maxRgb = 0.000000001;
     float maxInt = 0.000000001;
     int numPix;
 
     numPix = w*h*d*4;
     // calc maxima
     for(int i=0; i<numPix; i++)
     {
       if((i-3)%4 != 0)
       {
         if(buffer[i] > maxRgb)
           maxRgb = buffer[i];
       }
       else
       {
         if(buffer[i] > maxInt)
           maxInt = buffer[i];
       }
     }
 
     // write output, normalized uchar 0..255
     for(int i=0; i<numPix; i++)
     {
       if((i-3)%4 != 0)
         outImageBufferPointer[i] = (unsigned char) (255.0 * buffer[i] / maxRgb);
       else
         outImageBufferPointer[i] = (unsigned char) (255.0 * buffer[i] / maxInt);
     }
   }
 }
diff --git a/Modules/DiffusionImaging/FiberTracking/Algorithms/itkTractsToVectorImageFilter.cpp b/Modules/DiffusionImaging/FiberTracking/Algorithms/itkTractsToVectorImageFilter.cpp
index fb4db8575d..82ef991340 100644
--- a/Modules/DiffusionImaging/FiberTracking/Algorithms/itkTractsToVectorImageFilter.cpp
+++ b/Modules/DiffusionImaging/FiberTracking/Algorithms/itkTractsToVectorImageFilter.cpp
@@ -1,566 +1,566 @@
 #include "itkTractsToVectorImageFilter.h"
 
 // VTK
 #include <vtkPolyLine.h>
 #include <vtkCellArray.h>
 #include <vtkCellData.h>
 
 // ITK
 #include <itkTimeProbe.h>
 #include <itkImageRegionIterator.h>
 
 // misc
 #define _USE_MATH_DEFINES
 #include <math.h>
 #include <boost/progress.hpp>
 
 
 namespace itk{
 
 static bool CompareVectorLengths(const vnl_vector_fixed< double, 3 >& v1, const vnl_vector_fixed< double, 3 >& v2)
 {
     return (v1.magnitude()>v2.magnitude());
 }
 
 template< class PixelType >
 TractsToVectorImageFilter< PixelType >::TractsToVectorImageFilter():
     m_AngularThreshold(0.7),
     m_Epsilon(0.999),
     m_MaskImage(NULL),
     m_NormalizeVectors(false),
     m_UseWorkingCopy(true),
     m_MaxNumDirections(3),
     m_SizeThreshold(0.2),
     m_NumDirectionsImage(NULL),
     m_CreateDirectionImages(true)
 {
     this->SetNumberOfRequiredOutputs(1);
 }
 
 
 template< class PixelType >
 TractsToVectorImageFilter< PixelType >::~TractsToVectorImageFilter()
 {
 }
 
 
 template< class PixelType >
 vnl_vector_fixed<double, 3> TractsToVectorImageFilter< PixelType >::GetVnlVector(double point[])
 {
     vnl_vector_fixed<double, 3> vnlVector;
     vnlVector[0] = point[0];
     vnlVector[1] = point[1];
     vnlVector[2] = point[2];
     return vnlVector;
 }
 
 
 template< class PixelType >
 itk::Point<double, 3> TractsToVectorImageFilter< PixelType >::GetItkPoint(double point[])
 {
     itk::Point<double, 3> itkPoint;
     itkPoint[0] = point[0];
     itkPoint[1] = point[1];
     itkPoint[2] = point[2];
     return itkPoint;
 }
 
 template< class PixelType >
 void TractsToVectorImageFilter< PixelType >::GenerateData()
 {
     mitk::BaseGeometry::Pointer geometry = m_FiberBundle->GetGeometry();
 
     // calculate new image parameters
     itk::Vector<double> spacing;
     itk::Point<double> origin;
     itk::Matrix<double, 3, 3> direction;
     ImageRegion<3> imageRegion;
     if (!m_MaskImage.IsNull())
     {
         spacing = m_MaskImage->GetSpacing();
         imageRegion = m_MaskImage->GetLargestPossibleRegion();
         origin = m_MaskImage->GetOrigin();
         direction = m_MaskImage->GetDirection();
     }
     else
     {
         spacing = geometry->GetSpacing();
         origin = geometry->GetOrigin();
         mitk::BaseGeometry::BoundsArrayType bounds = geometry->GetBounds();
         origin[0] += bounds.GetElement(0);
         origin[1] += bounds.GetElement(2);
         origin[2] += bounds.GetElement(4);
 
         for (int i=0; i<3; i++)
             for (int j=0; j<3; j++)
                 direction[j][i] = geometry->GetMatrixColumn(i)[j];
         imageRegion.SetSize(0, geometry->GetExtent(0));
         imageRegion.SetSize(1, geometry->GetExtent(1));
         imageRegion.SetSize(2, geometry->GetExtent(2));
 
 
         m_MaskImage = ItkUcharImgType::New();
         m_MaskImage->SetSpacing( spacing );
         m_MaskImage->SetOrigin( origin );
         m_MaskImage->SetDirection( direction );
         m_MaskImage->SetRegions( imageRegion );
         m_MaskImage->Allocate();
         m_MaskImage->FillBuffer(1);
     }
     OutputImageType::RegionType::SizeType outImageSize = imageRegion.GetSize();
     m_OutImageSpacing = m_MaskImage->GetSpacing();
     m_ClusteredDirectionsContainer = ContainerType::New();
 
     // initialize num directions image
     m_NumDirectionsImage = ItkUcharImgType::New();
     m_NumDirectionsImage->SetSpacing( spacing );
     m_NumDirectionsImage->SetOrigin( origin );
     m_NumDirectionsImage->SetDirection( direction );
     m_NumDirectionsImage->SetRegions( imageRegion );
     m_NumDirectionsImage->Allocate();
     m_NumDirectionsImage->FillBuffer(0);
 
     // initialize direction images
     m_DirectionImageContainer = DirectionImageContainerType::New();
 
     // resample fiber bundle
     double minSpacing = 1;
     if(m_OutImageSpacing[0]<m_OutImageSpacing[1] && m_OutImageSpacing[0]<m_OutImageSpacing[2])
         minSpacing = m_OutImageSpacing[0];
     else if (m_OutImageSpacing[1] < m_OutImageSpacing[2])
         minSpacing = m_OutImageSpacing[1];
     else
         minSpacing = m_OutImageSpacing[2];
 
     if (m_UseWorkingCopy)
         m_FiberBundle = m_FiberBundle->GetDeepCopy();
 
     // resample fiber bundle for sufficient voxel coverage
-    m_FiberBundle->ResampleLinear(minSpacing/10);
+    m_FiberBundle->ResampleSpline(minSpacing/10);
 
     // iterate over all fibers
     vtkSmartPointer<vtkPolyData> fiberPolyData = m_FiberBundle->GetFiberPolyData();
     int numFibers = m_FiberBundle->GetNumFibers();
     m_DirectionsContainer = ContainerType::New();
 
     MITK_INFO << "Generating directions from tractogram";
     boost::progress_display disp(numFibers);
     for( int i=0; i<numFibers; i++ )
     {
         ++disp;
         vtkCell* cell = fiberPolyData->GetCell(i);
         int numPoints = cell->GetNumberOfPoints();
         vtkPoints* points = cell->GetPoints();
         if (numPoints<2)
             continue;
 
         vnl_vector_fixed<double, 3> dir;
         itk::Point<double, 3> worldPos;
         vnl_vector<double> v;
 
         for( int j=0; j<numPoints-1; j++)
         {
             // get current position along fiber in world coordinates
             double* temp = points->GetPoint(j);
             worldPos = GetItkPoint(temp);
             itk::Index<3> index;
             m_MaskImage->TransformPhysicalPointToIndex(worldPos, index);
             if (!m_MaskImage->GetLargestPossibleRegion().IsInside(index) || m_MaskImage->GetPixel(index)==0)
                 continue;
 
             // get fiber tangent direction at this position
             v = GetVnlVector(temp);
             dir = GetVnlVector(points->GetPoint(j+1))-v;
             if (dir.is_zero())
                 continue;
             dir.normalize();
 
             // add direction to container
             unsigned int idx = index[0] + outImageSize[0]*(index[1] + outImageSize[1]*index[2]);
             DirectionContainerType::Pointer dirCont;
             if (m_DirectionsContainer->IndexExists(idx))
             {
                 dirCont = m_DirectionsContainer->GetElement(idx);
                 if (dirCont.IsNull())
                 {
                     dirCont = DirectionContainerType::New();
                     dirCont->push_back(dir);
                     m_DirectionsContainer->InsertElement(idx, dirCont);
                 }
                 else
                     dirCont->push_back(dir);
             }
             else
             {
                 dirCont = DirectionContainerType::New();
                 dirCont->push_back(dir);
                 m_DirectionsContainer->InsertElement(idx, dirCont);
             }
         }
     }
 
     vtkSmartPointer<vtkCellArray> m_VtkCellArray = vtkSmartPointer<vtkCellArray>::New();
     vtkSmartPointer<vtkPoints>    m_VtkPoints = vtkSmartPointer<vtkPoints>::New();
 
     itk::ImageRegionIterator<ItkUcharImgType> dirIt(m_NumDirectionsImage, m_NumDirectionsImage->GetLargestPossibleRegion());
 
     MITK_INFO << "Clustering directions";
     boost::progress_display disp2(outImageSize[0]*outImageSize[1]*outImageSize[2]);
     while(!dirIt.IsAtEnd())
     {
         ++disp2;
         OutputImageType::IndexType index = dirIt.GetIndex();
         int idx = index[0]+(index[1]+index[2]*outImageSize[1])*outImageSize[0];
 
         if (!m_DirectionsContainer->IndexExists(idx))
         {
             ++dirIt;
             continue;
         }
         DirectionContainerType::Pointer dirCont = m_DirectionsContainer->GetElement(idx);
         if (dirCont.IsNull() || dirCont->empty())
         {
             ++dirIt;
             continue;
         }
 
         std::vector< double > lengths; lengths.resize(dirCont->size(), 1);  // all peaks have size 1
         DirectionContainerType::Pointer directions;
         if (m_MaxNumDirections>0)
         {
             directions = FastClustering(dirCont, lengths);
             std::sort( directions->begin(), directions->end(), CompareVectorLengths );
         }
         else
             directions = dirCont;
 
         unsigned int numDir = directions->size();
         if (m_MaxNumDirections>0 && numDir>m_MaxNumDirections)
             numDir = m_MaxNumDirections;
 
         int count = 0;
         for (unsigned int i=0; i<numDir; i++)
         {
             vtkSmartPointer<vtkPolyLine> container = vtkSmartPointer<vtkPolyLine>::New();
             itk::ContinuousIndex<double, 3> center;
             center[0] = index[0];
             center[1] = index[1];
             center[2] = index[2];
             itk::Point<double> worldCenter;
             m_MaskImage->TransformContinuousIndexToPhysicalPoint( center, worldCenter );
             DirectionType dir = directions->at(i);
 
             if (dir.magnitude()<m_SizeThreshold)
                 continue;
             count++;
 
 //            if (m_NormalizeVectors)
 //                dir.normalize();
 
             if (m_CreateDirectionImages && i<10)
             {
                 if (i==m_DirectionImageContainer->size())
                 {
                     ItkDirectionImageType::Pointer directionImage = ItkDirectionImageType::New();
                     directionImage->SetSpacing( spacing );
                     directionImage->SetOrigin( origin );
                     directionImage->SetDirection( direction );
                     directionImage->SetRegions( imageRegion );
                     directionImage->Allocate();
                     Vector< float, 3 > nullVec; nullVec.Fill(0.0);
                     directionImage->FillBuffer(nullVec);
                     m_DirectionImageContainer->InsertElement(i, directionImage);
                 }
 
                 // set direction image pixel
                 ItkDirectionImageType::Pointer directionImage = m_DirectionImageContainer->GetElement(i);
                 Vector< float, 3 > pixel;
                 pixel.SetElement(0, dir[0]);
                 pixel.SetElement(1, dir[1]);
                 pixel.SetElement(2, dir[2]);
                 directionImage->SetPixel(index, pixel);
             }
 
             // add direction to vector field (with spacing compensation)
             itk::Point<double> worldStart;
             worldStart[0] = worldCenter[0]-dir[0]/2*minSpacing;
             worldStart[1] = worldCenter[1]-dir[1]/2*minSpacing;
             worldStart[2] = worldCenter[2]-dir[2]/2*minSpacing;
             vtkIdType id = m_VtkPoints->InsertNextPoint(worldStart.GetDataPointer());
             container->GetPointIds()->InsertNextId(id);
             itk::Point<double> worldEnd;
             worldEnd[0] = worldCenter[0]+dir[0]/2*minSpacing;
             worldEnd[1] = worldCenter[1]+dir[1]/2*minSpacing;
             worldEnd[2] = worldCenter[2]+dir[2]/2*minSpacing;
             id = m_VtkPoints->InsertNextPoint(worldEnd.GetDataPointer());
             container->GetPointIds()->InsertNextId(id);
             m_VtkCellArray->InsertNextCell(container);
         }
         dirIt.Set(count);
         ++dirIt;
     }
 
     vtkSmartPointer<vtkPolyData> directionsPolyData = vtkSmartPointer<vtkPolyData>::New();
     directionsPolyData->SetPoints(m_VtkPoints);
     directionsPolyData->SetLines(m_VtkCellArray);
     m_OutputFiberBundle = mitk::FiberBundleX::New(directionsPolyData);
 }
 
 
 template< class PixelType >
 TractsToVectorImageFilter< PixelType >::DirectionContainerType::Pointer TractsToVectorImageFilter< PixelType >::FastClustering(DirectionContainerType::Pointer inDirs, std::vector< double > lengths)
 {
     DirectionContainerType::Pointer outDirs = DirectionContainerType::New();
     if (inDirs->size()<2)
         return inDirs;
 
     DirectionType oldMean, currentMean;
     std::vector< int > touched;
 
     // initialize
     touched.resize(inDirs->size(), 0);
     bool free = true;
     currentMean = inDirs->at(0);  // initialize first seed
     currentMean.normalize();
     double length = lengths.at(0);
     touched[0] = 1;
     std::vector< double > newLengths;
     bool meanChanged = false;
 
     double max = 0;
     while (free)
     {
         oldMean.fill(0.0);
 
         // start mean-shift clustering
         double angle = 0;
 
         while (fabs(dot_product(currentMean, oldMean))<0.99)
         {
             oldMean = currentMean;
             currentMean.fill(0.0);
             for (unsigned int i=0; i<inDirs->size(); i++)
             {
                 angle = dot_product(oldMean, inDirs->at(i));
                 if (angle>=m_AngularThreshold)
                 {
                     currentMean += inDirs->at(i);
                     if (meanChanged)
                         length += lengths.at(i);
                     touched[i] = 1;
                     meanChanged = true;
                 }
                 else if (-angle>=m_AngularThreshold)
                 {
                     currentMean -= inDirs->at(i);
                     if (meanChanged)
                         length += lengths.at(i);
                     touched[i] = 1;
                     meanChanged = true;
                 }
             }
             if(!meanChanged)
                 currentMean = oldMean;
             else
                 currentMean.normalize();
         }
 
         // found stable mean
         outDirs->push_back(currentMean);
         newLengths.push_back(length);
         if (length>max)
             max = length;
 
         // find next unused seed
         free = false;
         for (unsigned int i=0; i<touched.size(); i++)
             if (touched[i]==0)
             {
                 currentMean = inDirs->at(i);
                 free = true;
                 meanChanged = false;
                 length = lengths.at(i);
                 touched[i] = 1;
                 break;
             }
     }
 
     if (inDirs->size()==outDirs->size())
     {
         if (!m_NormalizeVectors && max>0)
             for (unsigned int i=0; i<outDirs->size(); i++)
                 outDirs->SetElement(i, outDirs->at(i)*newLengths.at(i)/max);
         return outDirs;
     }
     else
         return FastClustering(outDirs, newLengths);
 }
 
 
 //template< class PixelType >
 //std::vector< DirectionType > TractsToVectorImageFilter< PixelType >::Clustering(std::vector< DirectionType >& inDirs)
 //{
 //    std::vector< DirectionType > outDirs;
 //    if (inDirs.empty())
 //        return outDirs;
 //    DirectionType oldMean, currentMean, workingMean;
 
 //    std::vector< DirectionType > normalizedDirs;
 //    std::vector< int > touched;
 //    for (std::size_t i=0; i<inDirs.size(); i++)
 //    {
 //        normalizedDirs.push_back(inDirs[i]);
 //        normalizedDirs.back().normalize();
 //    }
 
 //    // initialize
 //    double max = 0.0;
 //    touched.resize(inDirs.size(), 0);
 //    for (std::size_t j=0; j<inDirs.size(); j++)
 //    {
 //        currentMean = inDirs[j];
 //        oldMean.fill(0.0);
 
 //        // start mean-shift clustering
 //        double angle = 0.0;
 //        int counter = 0;
 //        while ((currentMean-oldMean).magnitude()>0.0001)
 //        {
 //            counter = 0;
 //            oldMean = currentMean;
 //            workingMean = oldMean;
 //            workingMean.normalize();
 //            currentMean.fill(0.0);
 //            for (std::size_t i=0; i<normalizedDirs.size(); i++)
 //            {
 //                angle = dot_product(workingMean, normalizedDirs[i]);
 //                if (angle>=m_AngularThreshold)
 //                {
 //                    currentMean += inDirs[i];
 //                    counter++;
 //                }
 //                else if (-angle>=m_AngularThreshold)
 //                {
 //                    currentMean -= inDirs[i];
 //                    counter++;
 //                }
 //            }
 //        }
 
 //        // found stable mean
 //        if (counter>0)
 //        {
 //            bool add = true;
 //            DirectionType normMean = currentMean;
 //            normMean.normalize();
 //            for (std::size_t i=0; i<outDirs.size(); i++)
 //            {
 //                DirectionType dir = outDirs[i];
 //                dir.normalize();
 //                if ((normMean-dir).magnitude()<=0.0001)
 //                {
 //                    add = false;
 //                    break;
 //                }
 //            }
 
 //            currentMean /= counter;
 //            if (add)
 //            {
 //                double mag = currentMean.magnitude();
 //                if (mag>0)
 //                {
 //                    if (mag>max)
 //                        max = mag;
 
 //                    outDirs.push_back(currentMean);
 //                }
 //            }
 //        }
 //    }
 
 //    if (m_NormalizeVectors)
 //        for (std::size_t i=0; i<outDirs.size(); i++)
 //            outDirs[i].normalize();
 //    else if (max>0)
 //        for (std::size_t i=0; i<outDirs.size(); i++)
 //            outDirs[i] /= max;
 
 //    if (inDirs.size()==outDirs.size())
 //        return outDirs;
 //    else
 //        return FastClustering(outDirs);
 //}
 
 
 //template< class PixelType >
 //TractsToVectorImageFilter< PixelType >::DirectionContainerType::Pointer TractsToVectorImageFilter< PixelType >::MeanShiftClustering(DirectionContainerType::Pointer dirCont)
 //{
 //    DirectionContainerType::Pointer container = DirectionContainerType::New();
 
 //    double max = 0;
 //    for (DirectionContainerType::ConstIterator it = dirCont->Begin(); it!=dirCont->End(); ++it)
 //    {
 //        vnl_vector_fixed<double, 3> mean = ClusterStep(dirCont, it.Value());
 
 //        if (mean.is_zero())
 //            continue;
 //        bool addMean = true;
 
 //        for (DirectionContainerType::ConstIterator it2 = container->Begin(); it2!=container->End(); ++it2)
 //        {
 //            vnl_vector_fixed<double, 3> dir = it2.Value();
 //            double angle = fabs(dot_product(mean, dir)/(mean.magnitude()*dir.magnitude()));
 //            if (angle>=m_Epsilon)
 //            {
 //                addMean = false;
 //                break;
 //            }
 //        }
 
 //        if (addMean)
 //        {
 //            if (m_NormalizeVectors)
 //                mean.normalize();
 //            else if (mean.magnitude()>max)
 //                max = mean.magnitude();
 //            container->InsertElement(container->Size(), mean);
 //        }
 //    }
 
 //    // max normalize voxel directions
 //    if (max>0 && !m_NormalizeVectors)
 //        for (std::size_t i=0; i<container->Size(); i++)
 //            container->ElementAt(i) /= max;
 
 //    if (container->Size()<dirCont->Size())
 //        return MeanShiftClustering(container);
 //    else
 //        return container;
 //}
 
 
 //template< class PixelType >
 //vnl_vector_fixed<double, 3> TractsToVectorImageFilter< PixelType >::ClusterStep(DirectionContainerType::Pointer dirCont, vnl_vector_fixed<double, 3> currentMean)
 //{
 //    vnl_vector_fixed<double, 3> newMean; newMean.fill(0);
 
 //    for (DirectionContainerType::ConstIterator it = dirCont->Begin(); it!=dirCont->End(); ++it)
 //    {
 //        vnl_vector_fixed<double, 3> dir = it.Value();
 //        double angle = dot_product(currentMean, dir)/(currentMean.magnitude()*dir.magnitude());
 //        if (angle>=m_AngularThreshold)
 //            newMean += dir;
 //        else if (-angle>=m_AngularThreshold)
 //            newMean -= dir;
 //    }
 
 //    if (fabs(dot_product(currentMean, newMean)/(currentMean.magnitude()*newMean.magnitude()))>=m_Epsilon || newMean.is_zero())
 //        return newMean;
 //    else
 //        return ClusterStep(dirCont, newMean);
 //}
 }
 
 
 
diff --git a/Modules/DiffusionImaging/FiberTracking/IODataStructures/FiberBundleX/mitkFiberBundleX.cpp b/Modules/DiffusionImaging/FiberTracking/IODataStructures/FiberBundleX/mitkFiberBundleX.cpp
index 1456a19ab5..e911ac802f 100755
--- a/Modules/DiffusionImaging/FiberTracking/IODataStructures/FiberBundleX/mitkFiberBundleX.cpp
+++ b/Modules/DiffusionImaging/FiberTracking/IODataStructures/FiberBundleX/mitkFiberBundleX.cpp
@@ -1,1951 +1,1865 @@
 /*===================================================================
 
 The Medical Imaging Interaction Toolkit (MITK)
 
 Copyright (c) German Cancer Research Center,
 Division of Medical and Biological Informatics.
 All rights reserved.
 
 This software is distributed WITHOUT ANY WARRANTY; without
 even the implied warranty of MERCHANTABILITY or FITNESS FOR
 A PARTICULAR PURPOSE.
 
 See LICENSE.txt or http://www.mitk.org for details.
 
 ===================================================================*/
 
 
 #define _USE_MATH_DEFINES
 #include "mitkFiberBundleX.h"
 
 #include <mitkPlanarCircle.h>
 #include <mitkPlanarPolygon.h>
 #include <mitkPlanarFigureComposite.h>
 #include "mitkImagePixelReadAccessor.h"
 #include <mitkPixelTypeMultiplex.h>
 
 #include <vtkPointData.h>
 #include <vtkDataArray.h>
 #include <vtkUnsignedCharArray.h>
 #include <vtkPolyLine.h>
 #include <vtkCellArray.h>
 #include <vtkCellData.h>
 #include <vtkIdFilter.h>
 #include <vtkClipPolyData.h>
 #include <vtkPlane.h>
 #include <vtkDoubleArray.h>
 #include <vtkKochanekSpline.h>
 #include <vtkParametricFunctionSource.h>
 #include <vtkParametricSpline.h>
 #include <vtkPolygon.h>
 #include <vtkCleanPolyData.h>
 #include <cmath>
 #include <boost/progress.hpp>
 #include <vtkTransformPolyDataFilter.h>
 
 const char* mitk::FiberBundleX::COLORCODING_ORIENTATION_BASED = "Color_Orient";
 //const char* mitk::FiberBundleX::COLORCODING_FA_AS_OPACITY = "Color_Orient_FA_Opacity";
 const char* mitk::FiberBundleX::COLORCODING_FA_BASED = "FA_Values";
 const char* mitk::FiberBundleX::COLORCODING_CUSTOM = "custom";
 const char* mitk::FiberBundleX::FIBER_ID_ARRAY = "Fiber_IDs";
 
 using namespace std;
 
 mitk::FiberBundleX::FiberBundleX( vtkPolyData* fiberPolyData )
     : m_CurrentColorCoding(NULL)
     , m_NumFibers(0)
     , m_FiberSampling(0)
 {
     m_FiberPolyData = vtkSmartPointer<vtkPolyData>::New();
     if (fiberPolyData != NULL)
     {
         m_FiberPolyData = fiberPolyData;
         //m_FiberPolyData->DeepCopy(fiberPolyData);
         this->DoColorCodingOrientationBased();
     }
 
     this->UpdateFiberGeometry();
     this->SetColorCoding(COLORCODING_ORIENTATION_BASED);
     this->GenerateFiberIds();
 }
 
 mitk::FiberBundleX::~FiberBundleX()
 {
 
 }
 
 mitk::FiberBundleX::Pointer mitk::FiberBundleX::GetDeepCopy()
 {
     mitk::FiberBundleX::Pointer newFib = mitk::FiberBundleX::New(m_FiberPolyData);
     newFib->SetColorCoding(m_CurrentColorCoding);
     return newFib;
 }
 
 vtkSmartPointer<vtkPolyData> mitk::FiberBundleX::GeneratePolyDataByIds(std::vector<long> fiberIds)
 {
     MITK_DEBUG << "\n=====FINAL RESULT: fib_id ======\n";
     MITK_DEBUG << "Number of new Fibers: " << fiberIds.size();
     // iterate through the vectorcontainer hosting all desired fiber Ids
 
     vtkSmartPointer<vtkPolyData> newFiberPolyData = vtkSmartPointer<vtkPolyData>::New();
     vtkSmartPointer<vtkCellArray> newLineSet = vtkSmartPointer<vtkCellArray>::New();
     vtkSmartPointer<vtkPoints> newPointSet = vtkSmartPointer<vtkPoints>::New();
 
     // if FA array available, initialize fa double array
     // if color orient array is available init color array
     vtkSmartPointer<vtkDoubleArray> faValueArray;
     vtkSmartPointer<vtkUnsignedCharArray> colorsT;
     //colors and alpha value for each single point, RGBA = 4 components
     unsigned char rgba[4] = {0,0,0,0};
     int componentSize = sizeof(rgba);
 
     if (m_FiberIdDataSet->GetPointData()->HasArray(COLORCODING_FA_BASED)){
         MITK_DEBUG << "FA VALUES AVAILABLE, init array for new fiberbundle";
         faValueArray = vtkSmartPointer<vtkDoubleArray>::New();
     }
 
     if (m_FiberIdDataSet->GetPointData()->HasArray(COLORCODING_ORIENTATION_BASED)){
         MITK_DEBUG << "colorValues available, init array for new fiberbundle";
         colorsT = vtkUnsignedCharArray::New();
         colorsT->SetNumberOfComponents(componentSize);
         colorsT->SetName(COLORCODING_ORIENTATION_BASED);
     }
 
 
 
     std::vector<long>::iterator finIt = fiberIds.begin();
     while ( finIt != fiberIds.end() )
     {
         if (*finIt < 0 || *finIt>GetNumFibers()){
             MITK_INFO << "FiberID can not be negative or >NumFibers!!! check id Extraction!" << *finIt;
             break;
         }
 
         vtkSmartPointer<vtkCell> fiber = m_FiberIdDataSet->GetCell(*finIt);//->DeepCopy(fiber);
 
         vtkSmartPointer<vtkPoints> fibPoints = fiber->GetPoints();
 
         vtkSmartPointer<vtkPolyLine> newFiber = vtkSmartPointer<vtkPolyLine>::New();
         newFiber->GetPointIds()->SetNumberOfIds( fibPoints->GetNumberOfPoints() );
 
         for(int i=0; i<fibPoints->GetNumberOfPoints(); i++)
         {
             //            MITK_DEBUG << "id: " << fiber->GetPointId(i);
             //            MITK_DEBUG << fibPoints->GetPoint(i)[0] << " | " << fibPoints->GetPoint(i)[1] << " | " << fibPoints->GetPoint(i)[2];
             newFiber->GetPointIds()->SetId(i, newPointSet->GetNumberOfPoints());
             newPointSet->InsertNextPoint(fibPoints->GetPoint(i)[0], fibPoints->GetPoint(i)[1], fibPoints->GetPoint(i)[2]);
 
 
             if (m_FiberIdDataSet->GetPointData()->HasArray(COLORCODING_FA_BASED)){
                 //                MITK_DEBUG << m_FiberIdDataSet->GetPointData()->GetArray(FA_VALUE_ARRAY)->GetTuple(fiber->GetPointId(i));
             }
 
             if (m_FiberIdDataSet->GetPointData()->HasArray(COLORCODING_ORIENTATION_BASED)){
                 //                MITK_DEBUG << "ColorValue: " << m_FiberIdDataSet->GetPointData()->GetArray(COLORCODING_ORIENTATION_BASED)->GetTuple(fiber->GetPointId(i))[0];
             }
         }
 
         newLineSet->InsertNextCell(newFiber);
         ++finIt;
     }
 
     newFiberPolyData->SetPoints(newPointSet);
     newFiberPolyData->SetLines(newLineSet);
     MITK_DEBUG << "new fiberbundle polydata points: " << newFiberPolyData->GetNumberOfPoints();
     MITK_DEBUG << "new fiberbundle polydata lines: " << newFiberPolyData->GetNumberOfLines();
     MITK_DEBUG << "=====================\n";
 
     //    mitk::FiberBundleX::Pointer newFib = mitk::FiberBundleX::New(newFiberPolyData);
     return newFiberPolyData;
 }
 
 // merge two fiber bundles
 mitk::FiberBundleX::Pointer mitk::FiberBundleX::AddBundle(mitk::FiberBundleX* fib)
 {
     if (fib==NULL)
     {
         MITK_WARN << "trying to call AddBundle with NULL argument";
         return NULL;
     }
     MITK_INFO << "Adding fibers";
 
     vtkSmartPointer<vtkPolyData> vNewPolyData = vtkSmartPointer<vtkPolyData>::New();
     vtkSmartPointer<vtkCellArray> vNewLines = vtkSmartPointer<vtkCellArray>::New();
     vtkSmartPointer<vtkPoints> vNewPoints = vtkSmartPointer<vtkPoints>::New();
 
     // add current fiber bundle
     for (int i=0; i<m_FiberPolyData->GetNumberOfCells(); i++)
     {
         vtkCell* cell = m_FiberPolyData->GetCell(i);
         int numPoints = cell->GetNumberOfPoints();
         vtkPoints* points = cell->GetPoints();
 
         vtkSmartPointer<vtkPolyLine> container = vtkSmartPointer<vtkPolyLine>::New();
         for (int j=0; j<numPoints; j++)
         {
             double p[3];
             points->GetPoint(j, p);
 
             vtkIdType id = vNewPoints->InsertNextPoint(p);
             container->GetPointIds()->InsertNextId(id);
         }
         vNewLines->InsertNextCell(container);
     }
 
     // add new fiber bundle
     for (int i=0; i<fib->GetFiberPolyData()->GetNumberOfCells(); i++)
     {
         vtkCell* cell = fib->GetFiberPolyData()->GetCell(i);
         int numPoints = cell->GetNumberOfPoints();
         vtkPoints* points = cell->GetPoints();
 
         vtkSmartPointer<vtkPolyLine> container = vtkSmartPointer<vtkPolyLine>::New();
         for (int j=0; j<numPoints; j++)
         {
             double p[3];
             points->GetPoint(j, p);
 
             vtkIdType id = vNewPoints->InsertNextPoint(p);
             container->GetPointIds()->InsertNextId(id);
         }
         vNewLines->InsertNextCell(container);
     }
 
     // initialize polydata
     vNewPolyData->SetPoints(vNewPoints);
     vNewPolyData->SetLines(vNewLines);
 
     // initialize fiber bundle
     mitk::FiberBundleX::Pointer newFib = mitk::FiberBundleX::New(vNewPolyData);
     return newFib;
 }
 
 // subtract two fiber bundles
 mitk::FiberBundleX::Pointer mitk::FiberBundleX::SubtractBundle(mitk::FiberBundleX* fib)
 {
     MITK_INFO << "Subtracting fibers";
 
     vtkSmartPointer<vtkPolyData> vNewPolyData = vtkSmartPointer<vtkPolyData>::New();
     vtkSmartPointer<vtkCellArray> vNewLines = vtkSmartPointer<vtkCellArray>::New();
     vtkSmartPointer<vtkPoints> vNewPoints = vtkSmartPointer<vtkPoints>::New();
 
     // iterate over current fibers
     boost::progress_display disp(m_NumFibers);
     for( int i=0; i<m_NumFibers; i++ )
     {
         ++disp;
         vtkCell* cell = m_FiberPolyData->GetCell(i);
         int numPoints = cell->GetNumberOfPoints();
         vtkPoints* points = cell->GetPoints();
 
         if (points==NULL || numPoints<=0)
             continue;
 
         int numFibers2 = fib->GetNumFibers();
         bool contained = false;
         for( int i2=0; i2<numFibers2; i2++ )
         {
             vtkCell* cell2 = fib->GetFiberPolyData()->GetCell(i2);
             int numPoints2 = cell2->GetNumberOfPoints();
             vtkPoints* points2 = cell2->GetPoints();
 
             if (points2==NULL)// || numPoints2<=0)
                 continue;
 
             // check endpoints
             if (numPoints2==numPoints)
             {
                 itk::Point<float, 3> point_start = GetItkPoint(points->GetPoint(0));
                 itk::Point<float, 3> point_end = GetItkPoint(points->GetPoint(numPoints-1));
                 itk::Point<float, 3> point2_start = GetItkPoint(points2->GetPoint(0));
                 itk::Point<float, 3> point2_end = GetItkPoint(points2->GetPoint(numPoints2-1));
 
                 if ((point_start.SquaredEuclideanDistanceTo(point2_start)<=mitk::eps && point_end.SquaredEuclideanDistanceTo(point2_end)<=mitk::eps) ||
                         (point_start.SquaredEuclideanDistanceTo(point2_end)<=mitk::eps && point_end.SquaredEuclideanDistanceTo(point2_start)<=mitk::eps))
                 {
                     // further checking ???
                     contained = true;
                     break;
                 }
             }
         }
 
         // add to result because fiber is not subtracted
         if (!contained)
         {
             vtkSmartPointer<vtkPolyLine> container = vtkSmartPointer<vtkPolyLine>::New();
             for( int j=0; j<numPoints; j++)
             {
                 vtkIdType id = vNewPoints->InsertNextPoint(points->GetPoint(j));
                 container->GetPointIds()->InsertNextId(id);
             }
             vNewLines->InsertNextCell(container);
         }
     }
     if(vNewLines->GetNumberOfCells()==0)
         return NULL;
     // initialize polydata
     vNewPolyData->SetPoints(vNewPoints);
     vNewPolyData->SetLines(vNewLines);
 
     // initialize fiber bundle
     return mitk::FiberBundleX::New(vNewPolyData);
 }
 
 itk::Point<float, 3> mitk::FiberBundleX::GetItkPoint(double point[3])
 {
     itk::Point<float, 3> itkPoint;
     itkPoint[0] = point[0];
     itkPoint[1] = point[1];
     itkPoint[2] = point[2];
     return itkPoint;
 }
 
 /*
  * set polydata (additional flag to recompute fiber geometry, default = true)
  */
 void mitk::FiberBundleX::SetFiberPolyData(vtkSmartPointer<vtkPolyData> fiberPD, bool updateGeometry)
 {
     if (fiberPD == NULL)
         this->m_FiberPolyData = vtkSmartPointer<vtkPolyData>::New();
     else
     {
         m_FiberPolyData->DeepCopy(fiberPD);
         DoColorCodingOrientationBased();
     }
 
     m_NumFibers = m_FiberPolyData->GetNumberOfLines();
 
     if (updateGeometry)
         UpdateFiberGeometry();
     SetColorCoding(COLORCODING_ORIENTATION_BASED);
     GenerateFiberIds();
 }
 
 /*
  * return vtkPolyData
  */
 vtkSmartPointer<vtkPolyData> mitk::FiberBundleX::GetFiberPolyData() const
 {
     return m_FiberPolyData;
 }
 
 void mitk::FiberBundleX::DoColorCodingOrientationBased()
 {
     //===== FOR WRITING A TEST ========================
     //  colorT size == tupelComponents * tupelElements
     //  compare color results
     //  to cover this code 100% also polydata needed, where colorarray already exists
     //  + one fiber with exactly 1 point
     //  + one fiber with 0 points
     //=================================================
 
     /*  make sure that processing colorcoding is only called when necessary */
     if ( m_FiberPolyData->GetPointData()->HasArray(COLORCODING_ORIENTATION_BASED) &&
          m_FiberPolyData->GetNumberOfPoints() ==
          m_FiberPolyData->GetPointData()->GetArray(COLORCODING_ORIENTATION_BASED)->GetNumberOfTuples() )
     {
         // fiberstructure is already colorcoded
         MITK_DEBUG << " NO NEED TO REGENERATE COLORCODING! " ;
         this->ResetFiberOpacity();
         this->SetColorCoding(COLORCODING_ORIENTATION_BASED);
         return;
     }
 
     /* Finally, execute color calculation */
     vtkPoints* extrPoints = NULL;
     extrPoints = m_FiberPolyData->GetPoints();
     int numOfPoints = 0;
     if (extrPoints!=NULL)
         numOfPoints = extrPoints->GetNumberOfPoints();
 
     //colors and alpha value for each single point, RGBA = 4 components
     unsigned char rgba[4] = {0,0,0,0};
     //    int componentSize = sizeof(rgba);
     int componentSize = 4;
 
     vtkSmartPointer<vtkUnsignedCharArray> colorsT = vtkSmartPointer<vtkUnsignedCharArray>::New();
     colorsT->Allocate(numOfPoints * componentSize);
     colorsT->SetNumberOfComponents(componentSize);
     colorsT->SetName(COLORCODING_ORIENTATION_BASED);
 
     /* checkpoint: does polydata contain any fibers */
     int numOfFibers = m_FiberPolyData->GetNumberOfLines();
     if (numOfFibers < 1)
         return;
 
     /* extract single fibers of fiberBundle */
     vtkCellArray* fiberList = m_FiberPolyData->GetLines();
     fiberList->InitTraversal();
     for (int fi=0; fi<numOfFibers; ++fi) {
 
         vtkIdType* idList; // contains the point id's of the line
         vtkIdType pointsPerFiber; // number of points for current line
         fiberList->GetNextCell(pointsPerFiber, idList);
 
         /* single fiber checkpoints: is number of points valid */
         if (pointsPerFiber > 1)
         {
             /* operate on points of single fiber */
             for (int i=0; i <pointsPerFiber; ++i)
             {
                 /* process all points except starting and endpoint for calculating color value take current point, previous point and next point */
                 if (i<pointsPerFiber-1 && i > 0)
                 {
                     /* The color value of the current point is influenced by the previous point and next point. */
                     vnl_vector_fixed< double, 3 > currentPntvtk(extrPoints->GetPoint(idList[i])[0], extrPoints->GetPoint(idList[i])[1],extrPoints->GetPoint(idList[i])[2]);
                     vnl_vector_fixed< double, 3 > nextPntvtk(extrPoints->GetPoint(idList[i+1])[0], extrPoints->GetPoint(idList[i+1])[1], extrPoints->GetPoint(idList[i+1])[2]);
                     vnl_vector_fixed< double, 3 > prevPntvtk(extrPoints->GetPoint(idList[i-1])[0], extrPoints->GetPoint(idList[i-1])[1], extrPoints->GetPoint(idList[i-1])[2]);
 
                     vnl_vector_fixed< double, 3 > diff1;
                     diff1 = currentPntvtk - nextPntvtk;
 
                     vnl_vector_fixed< double, 3 > diff2;
                     diff2 = currentPntvtk - prevPntvtk;
 
                     vnl_vector_fixed< double, 3 > diff;
                     diff = (diff1 - diff2) / 2.0;
                     diff.normalize();
 
                     rgba[0] = (unsigned char) (255.0 * std::fabs(diff[0]));
                     rgba[1] = (unsigned char) (255.0 * std::fabs(diff[1]));
                     rgba[2] = (unsigned char) (255.0 * std::fabs(diff[2]));
                     rgba[3] = (unsigned char) (255.0);
                 }
                 else if (i==0)
                 {
                     /* First point has no previous point, therefore only diff1 is taken */
 
                     vnl_vector_fixed< double, 3 > currentPntvtk(extrPoints->GetPoint(idList[i])[0], extrPoints->GetPoint(idList[i])[1],extrPoints->GetPoint(idList[i])[2]);
                     vnl_vector_fixed< double, 3 > nextPntvtk(extrPoints->GetPoint(idList[i+1])[0], extrPoints->GetPoint(idList[i+1])[1], extrPoints->GetPoint(idList[i+1])[2]);
 
                     vnl_vector_fixed< double, 3 > diff1;
                     diff1 = currentPntvtk - nextPntvtk;
                     diff1.normalize();
 
                     rgba[0] = (unsigned char) (255.0 * std::fabs(diff1[0]));
                     rgba[1] = (unsigned char) (255.0 * std::fabs(diff1[1]));
                     rgba[2] = (unsigned char) (255.0 * std::fabs(diff1[2]));
                     rgba[3] = (unsigned char) (255.0);
                 }
                 else if (i==pointsPerFiber-1)
                 {
                     /* Last point has no next point, therefore only diff2 is taken */
                     vnl_vector_fixed< double, 3 > currentPntvtk(extrPoints->GetPoint(idList[i])[0], extrPoints->GetPoint(idList[i])[1],extrPoints->GetPoint(idList[i])[2]);
                     vnl_vector_fixed< double, 3 > prevPntvtk(extrPoints->GetPoint(idList[i-1])[0], extrPoints->GetPoint(idList[i-1])[1], extrPoints->GetPoint(idList[i-1])[2]);
 
                     vnl_vector_fixed< double, 3 > diff2;
                     diff2 = currentPntvtk - prevPntvtk;
                     diff2.normalize();
 
                     rgba[0] = (unsigned char) (255.0 * std::fabs(diff2[0]));
                     rgba[1] = (unsigned char) (255.0 * std::fabs(diff2[1]));
                     rgba[2] = (unsigned char) (255.0 * std::fabs(diff2[2]));
                     rgba[3] = (unsigned char) (255.0);
 
                 }
                 colorsT->InsertTupleValue(idList[i], rgba);
             } //end for loop
         }
         else if (pointsPerFiber == 1)
         {
             /* a single point does not define a fiber (use vertex mechanisms instead */
             continue;
         }
         else
         {
             MITK_DEBUG << "Fiber with 0 points detected... please check your tractography algorithm!" ;
             continue;
         }
     }//end for loop
 
     m_FiberPolyData->GetPointData()->AddArray(colorsT);
 
     this->SetColorCoding(COLORCODING_ORIENTATION_BASED);
 
     //mini test, shall be ported to MITK TESTINGS!
     if (colorsT->GetSize() != numOfPoints*componentSize)
         MITK_DEBUG << "ALLOCATION ERROR IN INITIATING COLOR ARRAY";
 }
 
 void mitk::FiberBundleX::DoColorCodingFaBased()
 {
     if(m_FiberPolyData->GetPointData()->HasArray(COLORCODING_FA_BASED) != 1 )
         return;
 
     this->SetColorCoding(COLORCODING_FA_BASED);
     //    this->GenerateFiberIds();
 }
 
 void mitk::FiberBundleX::DoUseFaFiberOpacity()
 {
     if(m_FiberPolyData->GetPointData()->HasArray(COLORCODING_FA_BASED) != 1 )
         return;
 
     if(m_FiberPolyData->GetPointData()->HasArray(COLORCODING_ORIENTATION_BASED) != 1 )
         return;
 
     vtkDoubleArray* FAValArray = (vtkDoubleArray*) m_FiberPolyData->GetPointData()->GetArray(COLORCODING_FA_BASED);
     vtkUnsignedCharArray* ColorArray = dynamic_cast<vtkUnsignedCharArray*>  (m_FiberPolyData->GetPointData()->GetArray(COLORCODING_ORIENTATION_BASED));
 
     for(long i=0; i<ColorArray->GetNumberOfTuples(); i++) {
         double faValue = FAValArray->GetValue(i);
         faValue = faValue * 255.0;
         ColorArray->SetComponent(i,3, (unsigned char) faValue );
     }
 
     this->SetColorCoding(COLORCODING_ORIENTATION_BASED);
     //    this->GenerateFiberIds();
 }
 
 void mitk::FiberBundleX::ResetFiberOpacity() {
     vtkUnsignedCharArray* ColorArray = dynamic_cast<vtkUnsignedCharArray*>  (m_FiberPolyData->GetPointData()->GetArray(COLORCODING_ORIENTATION_BASED));
     if (ColorArray==NULL)
         return;
     for(long i=0; i<ColorArray->GetNumberOfTuples(); i++)
         ColorArray->SetComponent(i,3, 255.0 );
 }
 
 void mitk::FiberBundleX::SetFAMap(mitk::Image::Pointer FAimage)
 {
     mitkPixelTypeMultiplex1( SetFAMap, FAimage->GetPixelType(), FAimage );
 }
 
 template <typename TPixel>
 void mitk::FiberBundleX::SetFAMap(const mitk::PixelType, mitk::Image::Pointer FAimage)
 {
     MITK_DEBUG << "SetFAMap";
     vtkSmartPointer<vtkDoubleArray> faValues = vtkSmartPointer<vtkDoubleArray>::New();
     faValues->SetName(COLORCODING_FA_BASED);
     faValues->Allocate(m_FiberPolyData->GetNumberOfPoints());
     faValues->SetNumberOfValues(m_FiberPolyData->GetNumberOfPoints());
 
     mitk::ImagePixelReadAccessor<TPixel,3> readFAimage (FAimage, FAimage->GetVolumeData(0));
 
     vtkPoints* pointSet = m_FiberPolyData->GetPoints();
     for(long i=0; i<m_FiberPolyData->GetNumberOfPoints(); ++i)
     {
         Point3D px;
         px[0] = pointSet->GetPoint(i)[0];
         px[1] = pointSet->GetPoint(i)[1];
         px[2] = pointSet->GetPoint(i)[2];
         double faPixelValue = 1-readFAimage.GetPixelByWorldCoordinates(px);
         faValues->InsertValue(i, faPixelValue);
     }
 
     m_FiberPolyData->GetPointData()->AddArray(faValues);
     this->GenerateFiberIds();
 
     if(m_FiberPolyData->GetPointData()->HasArray(COLORCODING_FA_BASED))
         MITK_DEBUG << "FA VALUE ARRAY SET";
 
 }
 
 
 void mitk::FiberBundleX::GenerateFiberIds()
 {
     if (m_FiberPolyData == NULL)
         return;
 
     vtkSmartPointer<vtkIdFilter> idFiberFilter = vtkSmartPointer<vtkIdFilter>::New();
     idFiberFilter->SetInputData(m_FiberPolyData);
     idFiberFilter->CellIdsOn();
     //  idFiberFilter->PointIdsOn(); // point id's are not needed
     idFiberFilter->SetIdsArrayName(FIBER_ID_ARRAY);
     idFiberFilter->FieldDataOn();
     idFiberFilter->Update();
 
     m_FiberIdDataSet = idFiberFilter->GetOutput();
 
     MITK_DEBUG << "Generating Fiber Ids...[done] | " << m_FiberIdDataSet->GetNumberOfCells();
 
 }
 
 mitk::FiberBundleX::Pointer mitk::FiberBundleX::ExtractFiberSubset(ItkUcharImgType* mask, bool anyPoint, bool invert)
 {
     vtkSmartPointer<vtkPolyData> polyData = m_FiberPolyData;
     if (anyPoint)
     {
         float minSpacing = 1;
         if(mask->GetSpacing()[0]<mask->GetSpacing()[1] && mask->GetSpacing()[0]<mask->GetSpacing()[2])
             minSpacing = mask->GetSpacing()[0];
         else if (mask->GetSpacing()[1] < mask->GetSpacing()[2])
             minSpacing = mask->GetSpacing()[1];
         else
             minSpacing = mask->GetSpacing()[2];
 
         mitk::FiberBundleX::Pointer fibCopy = this->GetDeepCopy();
-        fibCopy->ResampleLinear(minSpacing/5);
+        fibCopy->ResampleSpline(minSpacing/5);
         polyData = fibCopy->GetFiberPolyData();
     }
     vtkSmartPointer<vtkPoints> vtkNewPoints = vtkSmartPointer<vtkPoints>::New();
     vtkSmartPointer<vtkCellArray> vtkNewCells = vtkSmartPointer<vtkCellArray>::New();
 
     MITK_INFO << "Extracting fibers";
     boost::progress_display disp(m_NumFibers);
     for (int i=0; i<m_NumFibers; i++)
     {
         ++disp;
 
         vtkCell* cell = polyData->GetCell(i);
         int numPoints = cell->GetNumberOfPoints();
         vtkPoints* points = cell->GetPoints();
 
         vtkCell* cellOriginal = m_FiberPolyData->GetCell(i);
         int numPointsOriginal = cellOriginal->GetNumberOfPoints();
         vtkPoints* pointsOriginal = cellOriginal->GetPoints();
 
         vtkSmartPointer<vtkPolyLine> container = vtkSmartPointer<vtkPolyLine>::New();
 
         if (numPoints>1 && numPointsOriginal)
         {
             if (anyPoint)
             {
                 if (!invert)
                 {
                     for (int j=0; j<numPoints; j++)
                     {
                         double* p = points->GetPoint(j);
 
                         itk::Point<float, 3> itkP;
                         itkP[0] = p[0]; itkP[1] = p[1]; itkP[2] = p[2];
                         itk::Index<3> idx;
                         mask->TransformPhysicalPointToIndex(itkP, idx);
 
                         if ( mask->GetPixel(idx)>0 && mask->GetLargestPossibleRegion().IsInside(idx) )
                         {
                             for (int k=0; k<numPointsOriginal; k++)
                             {
                                 double* p = pointsOriginal->GetPoint(k);
                                 vtkIdType id = vtkNewPoints->InsertNextPoint(p);
                                 container->GetPointIds()->InsertNextId(id);
                             }
                             break;
                         }
                     }
                 }
                 else
                 {
                     bool includeFiber = true;
                     for (int j=0; j<numPoints; j++)
                     {
                         double* p = points->GetPoint(j);
 
                         itk::Point<float, 3> itkP;
                         itkP[0] = p[0]; itkP[1] = p[1]; itkP[2] = p[2];
                         itk::Index<3> idx;
                         mask->TransformPhysicalPointToIndex(itkP, idx);
 
                         if ( mask->GetPixel(idx)>0 && mask->GetLargestPossibleRegion().IsInside(idx) )
                         {
                             includeFiber = false;
                             break;
                         }
                     }
                     if (includeFiber)
                     {
 
                         for (int k=0; k<numPointsOriginal; k++)
                         {
                             double* p = pointsOriginal->GetPoint(k);
                             vtkIdType id = vtkNewPoints->InsertNextPoint(p);
                             container->GetPointIds()->InsertNextId(id);
                         }
                     }
                 }
             }
             else
             {
                 double* start = pointsOriginal->GetPoint(0);
                 itk::Point<float, 3> itkStart;
                 itkStart[0] = start[0]; itkStart[1] = start[1]; itkStart[2] = start[2];
                 itk::Index<3> idxStart;
                 mask->TransformPhysicalPointToIndex(itkStart, idxStart);
 
                 double* end = pointsOriginal->GetPoint(numPointsOriginal-1);
                 itk::Point<float, 3> itkEnd;
                 itkEnd[0] = end[0]; itkEnd[1] = end[1]; itkEnd[2] = end[2];
                 itk::Index<3> idxEnd;
                 mask->TransformPhysicalPointToIndex(itkEnd, idxEnd);
 
                 if ( mask->GetPixel(idxStart)>0 && mask->GetPixel(idxEnd)>0 && mask->GetLargestPossibleRegion().IsInside(idxStart) && mask->GetLargestPossibleRegion().IsInside(idxEnd) )
                 {
                     for (int j=0; j<numPointsOriginal; j++)
                     {
                         double* p = pointsOriginal->GetPoint(j);
                         vtkIdType id = vtkNewPoints->InsertNextPoint(p);
                         container->GetPointIds()->InsertNextId(id);
                     }
                 }
             }
         }
 
         vtkNewCells->InsertNextCell(container);
     }
 
     if (vtkNewCells->GetNumberOfCells()<=0)
         return NULL;
 
     vtkSmartPointer<vtkPolyData> newPolyData = vtkSmartPointer<vtkPolyData>::New();
     newPolyData->SetPoints(vtkNewPoints);
     newPolyData->SetLines(vtkNewCells);
     return mitk::FiberBundleX::New(newPolyData);
 }
 
 mitk::FiberBundleX::Pointer mitk::FiberBundleX::RemoveFibersOutside(ItkUcharImgType* mask, bool invert)
 {
     float minSpacing = 1;
     if(mask->GetSpacing()[0]<mask->GetSpacing()[1] && mask->GetSpacing()[0]<mask->GetSpacing()[2])
         minSpacing = mask->GetSpacing()[0];
     else if (mask->GetSpacing()[1] < mask->GetSpacing()[2])
         minSpacing = mask->GetSpacing()[1];
     else
         minSpacing = mask->GetSpacing()[2];
 
     mitk::FiberBundleX::Pointer fibCopy = this->GetDeepCopy();
-    fibCopy->ResampleLinear(minSpacing/10);
+    fibCopy->ResampleSpline(minSpacing/10);
     vtkSmartPointer<vtkPolyData> polyData =fibCopy->GetFiberPolyData();
 
     vtkSmartPointer<vtkPoints> vtkNewPoints = vtkSmartPointer<vtkPoints>::New();
     vtkSmartPointer<vtkCellArray> vtkNewCells = vtkSmartPointer<vtkCellArray>::New();
 
     MITK_INFO << "Cutting fibers";
     boost::progress_display disp(m_NumFibers);
     for (int i=0; i<m_NumFibers; i++)
     {
         ++disp;
 
         vtkCell* cell = polyData->GetCell(i);
         int numPoints = cell->GetNumberOfPoints();
         vtkPoints* points = cell->GetPoints();
 
         vtkSmartPointer<vtkPolyLine> container = vtkSmartPointer<vtkPolyLine>::New();
         if (numPoints>1)
         {
             int newNumPoints = 0;
             for (int j=0; j<numPoints; j++)
             {
                 double* p = points->GetPoint(j);
 
                 itk::Point<float, 3> itkP;
                 itkP[0] = p[0]; itkP[1] = p[1]; itkP[2] = p[2];
                 itk::Index<3> idx;
                 mask->TransformPhysicalPointToIndex(itkP, idx);
 
                 if ( mask->GetPixel(idx)>0 && mask->GetLargestPossibleRegion().IsInside(idx) && !invert )
                 {
                     vtkIdType id = vtkNewPoints->InsertNextPoint(p);
                     container->GetPointIds()->InsertNextId(id);
                     newNumPoints++;
                 }
                 else if ( (mask->GetPixel(idx)<=0 || !mask->GetLargestPossibleRegion().IsInside(idx)) && invert )
                 {
                     vtkIdType id = vtkNewPoints->InsertNextPoint(p);
                     container->GetPointIds()->InsertNextId(id);
                     newNumPoints++;
                 }
                 else if (newNumPoints>0)
                 {
                     vtkNewCells->InsertNextCell(container);
 
                     newNumPoints = 0;
                     container = vtkSmartPointer<vtkPolyLine>::New();
                 }
             }
 
             if (newNumPoints>0)
                 vtkNewCells->InsertNextCell(container);
         }
 
     }
 
     if (vtkNewCells->GetNumberOfCells()<=0)
         return NULL;
 
     vtkSmartPointer<vtkPolyData> newPolyData = vtkSmartPointer<vtkPolyData>::New();
     newPolyData->SetPoints(vtkNewPoints);
     newPolyData->SetLines(vtkNewCells);
     mitk::FiberBundleX::Pointer newFib = mitk::FiberBundleX::New(newPolyData);
-    newFib->ResampleLinear(minSpacing/2);
+    newFib->ResampleSpline(minSpacing/2);
     return newFib;
 }
 
 mitk::FiberBundleX::Pointer mitk::FiberBundleX::ExtractFiberSubset(BaseData* roi)
 {
     if (roi==NULL || !(dynamic_cast<PlanarFigure*>(roi) || dynamic_cast<PlanarFigureComposite*>(roi)) )
         return NULL;
 
     std::vector<long> tmp = ExtractFiberIdSubset(roi);
 
     if (tmp.size()<=0)
         return mitk::FiberBundleX::New();
     vtkSmartPointer<vtkPolyData> pTmp = GeneratePolyDataByIds(tmp);
     return mitk::FiberBundleX::New(pTmp);
 }
 
 std::vector<long> mitk::FiberBundleX::ExtractFiberIdSubset(BaseData* roi)
 {
     std::vector<long> result;
     if (roi==NULL)
         return result;
 
     mitk::PlanarFigureComposite::Pointer pfc = dynamic_cast<mitk::PlanarFigureComposite*>(roi);
     if (!pfc.IsNull()) // handle composite
     {
         switch (pfc->getOperationType())
         {
         case 0: // AND
         {
             result = this->ExtractFiberIdSubset(pfc->getChildAt(0));
             std::vector<long>::iterator it;
             for (int i=1; i<pfc->getNumberOfChildren(); ++i)
             {
                 std::vector<long> inRoi = this->ExtractFiberIdSubset(pfc->getChildAt(i));
 
                 std::vector<long> rest(std::min(result.size(),inRoi.size()));
                 it = std::set_intersection(result.begin(), result.end(), inRoi.begin(), inRoi.end(), rest.begin() );
                 rest.resize( it - rest.begin() );
                 result = rest;
             }
             break;
         }
         case 1: // OR
         {
             result = ExtractFiberIdSubset(pfc->getChildAt(0));
             std::vector<long>::iterator it;
             for (int i=1; i<pfc->getNumberOfChildren(); ++i)
             {
                 it = result.end();
                 std::vector<long> inRoi = ExtractFiberIdSubset(pfc->getChildAt(i));
                 result.insert(it, inRoi.begin(), inRoi.end());
             }
 
             // remove duplicates
             sort(result.begin(), result.end());
             it = unique(result.begin(), result.end());
             result.resize( it - result.begin() );
             break;
         }
         case 2: // NOT
         {
             for(long i=0; i<this->GetNumFibers(); i++)
                 result.push_back(i);
 
             std::vector<long>::iterator it;
             for (long i=0; i<pfc->getNumberOfChildren(); ++i)
             {
                 std::vector<long> inRoi = ExtractFiberIdSubset(pfc->getChildAt(i));
 
                 std::vector<long> rest(result.size()-inRoi.size());
                 it = std::set_difference(result.begin(), result.end(), inRoi.begin(), inRoi.end(), rest.begin() );
                 rest.resize( it - rest.begin() );
                 result = rest;
             }
             break;
         }
         }
     }
     else if ( dynamic_cast<mitk::PlanarFigure*>(roi) )  // actual extraction
     {
         mitk::PlanarFigure::Pointer planarFigure = dynamic_cast<mitk::PlanarFigure*>(roi);
         Vector3D planeNormal = planarFigure->GetPlaneGeometry()->GetNormal();
         planeNormal.Normalize();
         Point3D planeOrigin = planarFigure->GetPlaneGeometry()->GetOrigin();
 
         // define cutting plane by ROI geometry (PlanarFigure)
         vtkSmartPointer<vtkPlane> plane = vtkSmartPointer<vtkPlane>::New();
         plane->SetOrigin(planeOrigin[0],planeOrigin[1],planeOrigin[2]);
         plane->SetNormal(planeNormal[0],planeNormal[1],planeNormal[2]);
 
         // get all fiber/plane intersection points
         vtkSmartPointer<vtkClipPolyData> clipper = vtkSmartPointer<vtkClipPolyData>::New();
         clipper->SetInputData(m_FiberIdDataSet);
         clipper->SetClipFunction(plane);
         clipper->GenerateClipScalarsOn();
         clipper->GenerateClippedOutputOn();
         clipper->Update();
         vtkSmartPointer<vtkPolyData> clipperout = clipper->GetClippedOutput();
         if (!clipperout->GetCellData()->HasArray(FIBER_ID_ARRAY))
             return result;
 
         vtkSmartPointer<vtkDataArray> distanceList = clipperout->GetPointData()->GetScalars();
         vtkIdType numPoints =  distanceList->GetNumberOfTuples();
 
         std::vector<int> pointsOnPlane;
         pointsOnPlane.reserve(numPoints);
         for (int i=0; i<numPoints; ++i)
         {
             double distance = distanceList->GetTuple(i)[0];
             // check if point is on plane
             if (distance >= -0.01 && distance <= 0.01)
                 pointsOnPlane.push_back(i);
         }
         if (pointsOnPlane.empty())
             return result;
 
         // get all point IDs inside the ROI
         std::vector<int> pointsInROI;
         pointsInROI.reserve(pointsOnPlane.size());
         mitk::PlanarCircle::Pointer circleName = mitk::PlanarCircle::New();
         mitk::PlanarPolygon::Pointer polyName = mitk::PlanarPolygon::New();
         if ( planarFigure->GetNameOfClass() == circleName->GetNameOfClass() )
         {
             //calculate circle radius
             mitk::Point3D V1w = planarFigure->GetWorldControlPoint(0); //centerPoint
             mitk::Point3D V2w  = planarFigure->GetWorldControlPoint(1); //radiusPoint
 
             double radius = V1w.EuclideanDistanceTo(V2w);
             radius *= radius;
 
             for (unsigned int i=0; i<pointsOnPlane.size(); i++)
             {
                 double p[3]; clipperout->GetPoint(pointsOnPlane[i], p);
                 double dist = (p[0]-V1w[0])*(p[0]-V1w[0])+(p[1]-V1w[1])*(p[1]-V1w[1])+(p[2]-V1w[2])*(p[2]-V1w[2]);
                 if( dist <= radius)
                     pointsInROI.push_back(pointsOnPlane[i]);
             }
         }
         else if ( planarFigure->GetNameOfClass() == polyName->GetNameOfClass() )
         {
             //create vtkPolygon using controlpoints from planarFigure polygon
             vtkSmartPointer<vtkPolygon> polygonVtk = vtkSmartPointer<vtkPolygon>::New();
             for (unsigned int i=0; i<planarFigure->GetNumberOfControlPoints(); ++i)
             {
                 itk::Point<double,3> p = planarFigure->GetWorldControlPoint(i);
                 polygonVtk->GetPoints()->InsertNextPoint(p[0], p[1], p[2] );
             }
             //prepare everything for using pointInPolygon function
             double n[3];
             polygonVtk->ComputeNormal(polygonVtk->GetPoints()->GetNumberOfPoints(), static_cast<double*>(polygonVtk->GetPoints()->GetData()->GetVoidPointer(0)), n);
             double bounds[6];
             polygonVtk->GetPoints()->GetBounds(bounds);
 
             for (unsigned int i=0; i<pointsOnPlane.size(); i++)
             {
                 double p[3]; clipperout->GetPoint(pointsOnPlane[i], p);
                 int isInPolygon = polygonVtk->PointInPolygon(p, polygonVtk->GetPoints()->GetNumberOfPoints(), static_cast<double*>(polygonVtk->GetPoints()->GetData()->GetVoidPointer(0)), bounds, n);
                 if( isInPolygon )
                     pointsInROI.push_back(pointsOnPlane[i]);
             }
         }
         if (pointsInROI.empty())
             return result;
 
         // get the fiber IDs corresponding to all clipped points
         std::vector< long > pointToFiberMap; // pointToFiberMap[PointID] = FiberIndex
         pointToFiberMap.resize(clipperout->GetNumberOfPoints());
 
         vtkCellArray* clipperlines = clipperout->GetLines();
         clipperlines->InitTraversal();
         for (int i=0, ic=0 ; i<clipperlines->GetNumberOfCells(); i++, ic+=3)
         {
             // ic is the index counter for the cells hosting the desired information. each cell consits of 3 items.
             long fiberID = clipperout->GetCellData()->GetArray(FIBER_ID_ARRAY)->GetTuple(i)[0];
             vtkIdType numPoints;
             vtkIdType* pointIDs;
             clipperlines->GetCell(ic, numPoints, pointIDs);
 
             for (long j=0; j<numPoints; j++)
                 pointToFiberMap[ pointIDs[j] ] = fiberID;
         }
 
         // get the fiber IDs corresponding to the ID of a point inside the ROI
         result.reserve(pointsInROI.size());
         for (unsigned long k = 0; k < pointsInROI.size(); k++)
         {
             if (pointToFiberMap[pointsInROI[k]]<=GetNumFibers() && pointToFiberMap[pointsInROI[k]]>=0)
                 result.push_back( pointToFiberMap[pointsInROI[k]] );
             else
                 MITK_INFO << "ERROR in ExtractFiberIdSubset; impossible fiber id detected";
         }
 
         // remove duplicates
         std::vector<long>::iterator it;
         sort(result.begin(), result.end());
         it = unique (result.begin(), result.end());
         result.resize( it - result.begin() );
     }
 
     return result;
 }
 
 void mitk::FiberBundleX::UpdateFiberGeometry()
 {
     vtkSmartPointer<vtkCleanPolyData> cleaner = vtkSmartPointer<vtkCleanPolyData>::New();
     cleaner->SetInputData(m_FiberPolyData);
     cleaner->PointMergingOff();
     cleaner->Update();
     m_FiberPolyData = cleaner->GetOutput();
 
     m_FiberLengths.clear();
     m_MeanFiberLength = 0;
     m_MedianFiberLength = 0;
     m_LengthStDev = 0;
     m_NumFibers = m_FiberPolyData->GetNumberOfCells();
 
     if (m_NumFibers<=0) // no fibers present; apply default geometry
     {
         m_MinFiberLength = 0;
         m_MaxFiberLength = 0;
         mitk::Geometry3D::Pointer geometry = mitk::Geometry3D::New();
         geometry->SetImageGeometry(false);
         float b[] = {0, 1, 0, 1, 0, 1};
         geometry->SetFloatBounds(b);
         SetGeometry(geometry);
         return;
     }
     double b[6];
     m_FiberPolyData->GetBounds(b);
 
     // calculate statistics
     for (int i=0; i<m_FiberPolyData->GetNumberOfCells(); i++)
     {
         vtkCell* cell = m_FiberPolyData->GetCell(i);
         int p = cell->GetNumberOfPoints();
         vtkPoints* points = cell->GetPoints();
         float length = 0;
         for (int j=0; j<p-1; j++)
         {
             double p1[3];
             points->GetPoint(j, p1);
             double p2[3];
             points->GetPoint(j+1, p2);
 
             float dist = std::sqrt((p1[0]-p2[0])*(p1[0]-p2[0])+(p1[1]-p2[1])*(p1[1]-p2[1])+(p1[2]-p2[2])*(p1[2]-p2[2]));
             length += dist;
         }
         m_FiberLengths.push_back(length);
         m_MeanFiberLength += length;
         if (i==0)
         {
             m_MinFiberLength = length;
             m_MaxFiberLength = length;
         }
         else
         {
             if (length<m_MinFiberLength)
                 m_MinFiberLength = length;
             if (length>m_MaxFiberLength)
                 m_MaxFiberLength = length;
         }
     }
     m_MeanFiberLength /= m_NumFibers;
 
     std::vector< float > sortedLengths = m_FiberLengths;
     std::sort(sortedLengths.begin(), sortedLengths.end());
     for (int i=0; i<m_NumFibers; i++)
         m_LengthStDev += (m_MeanFiberLength-sortedLengths.at(i))*(m_MeanFiberLength-sortedLengths.at(i));
     if (m_NumFibers>1)
         m_LengthStDev /= (m_NumFibers-1);
     else
         m_LengthStDev = 0;
     m_LengthStDev = std::sqrt(m_LengthStDev);
     m_MedianFiberLength = sortedLengths.at(m_NumFibers/2);
 
     mitk::Geometry3D::Pointer geometry = mitk::Geometry3D::New();
     geometry->SetFloatBounds(b);
     this->SetGeometry(geometry);
 
     m_UpdateTime3D.Modified();
     m_UpdateTime2D.Modified();
 }
 
 std::vector<std::string> mitk::FiberBundleX::GetAvailableColorCodings()
 {
     std::vector<std::string> availableColorCodings;
     int numColors = m_FiberPolyData->GetPointData()->GetNumberOfArrays();
     for(int i=0; i<numColors; i++)
     {
         availableColorCodings.push_back(m_FiberPolyData->GetPointData()->GetArrayName(i));
     }
 
     //this controlstructure shall be implemented by the calling method
     if (availableColorCodings.empty())
         MITK_DEBUG << "no colorcodings available in fiberbundleX";
 
     return availableColorCodings;
 }
 
 
 char* mitk::FiberBundleX::GetCurrentColorCoding()
 {
     return m_CurrentColorCoding;
 }
 
 void mitk::FiberBundleX::SetColorCoding(const char* requestedColorCoding)
 {
     if (requestedColorCoding==NULL)
         return;
 
     if( strcmp (COLORCODING_ORIENTATION_BASED,requestedColorCoding) == 0 )    {
         this->m_CurrentColorCoding = (char*) COLORCODING_ORIENTATION_BASED;
 
     } else if( strcmp (COLORCODING_FA_BASED,requestedColorCoding) == 0 ) {
         this->m_CurrentColorCoding = (char*) COLORCODING_FA_BASED;
 
     } else if( strcmp (COLORCODING_CUSTOM,requestedColorCoding) == 0 ) {
         this->m_CurrentColorCoding = (char*) COLORCODING_CUSTOM;
 
     } else {
         MITK_DEBUG << "FIBERBUNDLE X: UNKNOWN COLORCODING in FIBERBUNDLEX Datastructure";
         this->m_CurrentColorCoding = (char*) COLORCODING_CUSTOM; //will cause blank colorcoding of fibers
     }
 
     m_UpdateTime3D.Modified();
     m_UpdateTime2D.Modified();
 }
 
 itk::Matrix< double, 3, 3 > mitk::FiberBundleX::TransformMatrix(itk::Matrix< double, 3, 3 > m, double rx, double ry, double rz)
 {
     rx = rx*M_PI/180;
     ry = ry*M_PI/180;
     rz = rz*M_PI/180;
 
     itk::Matrix< double, 3, 3 > rotX; rotX.SetIdentity();
     rotX[1][1] = cos(rx);
     rotX[2][2] = rotX[1][1];
     rotX[1][2] = -sin(rx);
     rotX[2][1] = -rotX[1][2];
 
     itk::Matrix< double, 3, 3 > rotY; rotY.SetIdentity();
     rotY[0][0] = cos(ry);
     rotY[2][2] = rotY[0][0];
     rotY[0][2] = sin(ry);
     rotY[2][0] = -rotY[0][2];
 
     itk::Matrix< double, 3, 3 > rotZ; rotZ.SetIdentity();
     rotZ[0][0] = cos(rz);
     rotZ[1][1] = rotZ[0][0];
     rotZ[0][1] = -sin(rz);
     rotZ[1][0] = -rotZ[0][1];
 
     itk::Matrix< double, 3, 3 > rot = rotZ*rotY*rotX;
 
     m = rot*m;
 
     return m;
 }
 
 itk::Point<float, 3> mitk::FiberBundleX::TransformPoint(vnl_vector_fixed< double, 3 > point, double rx, double ry, double rz, double tx, double ty, double tz)
 {
     rx = rx*M_PI/180;
     ry = ry*M_PI/180;
     rz = rz*M_PI/180;
 
     vnl_matrix_fixed< double, 3, 3 > rotX; rotX.set_identity();
     rotX[1][1] = cos(rx);
     rotX[2][2] = rotX[1][1];
     rotX[1][2] = -sin(rx);
     rotX[2][1] = -rotX[1][2];
 
     vnl_matrix_fixed< double, 3, 3 > rotY; rotY.set_identity();
     rotY[0][0] = cos(ry);
     rotY[2][2] = rotY[0][0];
     rotY[0][2] = sin(ry);
     rotY[2][0] = -rotY[0][2];
 
     vnl_matrix_fixed< double, 3, 3 > rotZ; rotZ.set_identity();
     rotZ[0][0] = cos(rz);
     rotZ[1][1] = rotZ[0][0];
     rotZ[0][1] = -sin(rz);
     rotZ[1][0] = -rotZ[0][1];
 
     vnl_matrix_fixed< double, 3, 3 > rot = rotZ*rotY*rotX;
 
     mitk::BaseGeometry::Pointer geom = this->GetGeometry();
     mitk::Point3D center = geom->GetCenter();
 
     point[0] -= center[0];
     point[1] -= center[1];
     point[2] -= center[2];
     point = rot*point;
     point[0] += center[0]+tx;
     point[1] += center[1]+ty;
     point[2] += center[2]+tz;
     itk::Point<float, 3> out; out[0] = point[0]; out[1] = point[1]; out[2] = point[2];
     return out;
 }
 
 void mitk::FiberBundleX::TransformFibers(double rx, double ry, double rz, double tx, double ty, double tz)
 {
     rx = rx*M_PI/180;
     ry = ry*M_PI/180;
     rz = rz*M_PI/180;
 
     vnl_matrix_fixed< double, 3, 3 > rotX; rotX.set_identity();
     rotX[1][1] = cos(rx);
     rotX[2][2] = rotX[1][1];
     rotX[1][2] = -sin(rx);
     rotX[2][1] = -rotX[1][2];
 
     vnl_matrix_fixed< double, 3, 3 > rotY; rotY.set_identity();
     rotY[0][0] = cos(ry);
     rotY[2][2] = rotY[0][0];
     rotY[0][2] = sin(ry);
     rotY[2][0] = -rotY[0][2];
 
     vnl_matrix_fixed< double, 3, 3 > rotZ; rotZ.set_identity();
     rotZ[0][0] = cos(rz);
     rotZ[1][1] = rotZ[0][0];
     rotZ[0][1] = -sin(rz);
     rotZ[1][0] = -rotZ[0][1];
 
     vnl_matrix_fixed< double, 3, 3 > rot = rotZ*rotY*rotX;
 
     mitk::BaseGeometry::Pointer geom = this->GetGeometry();
     mitk::Point3D center = geom->GetCenter();
 
     vtkSmartPointer<vtkPoints> vtkNewPoints = vtkSmartPointer<vtkPoints>::New();
     vtkSmartPointer<vtkCellArray> vtkNewCells = vtkSmartPointer<vtkCellArray>::New();
 
     for (int i=0; i<m_NumFibers; i++)
     {
         vtkCell* cell = m_FiberPolyData->GetCell(i);
         int numPoints = cell->GetNumberOfPoints();
         vtkPoints* points = cell->GetPoints();
 
         vtkSmartPointer<vtkPolyLine> container = vtkSmartPointer<vtkPolyLine>::New();
         for (int j=0; j<numPoints; j++)
         {
             double* p = points->GetPoint(j);
             vnl_vector_fixed< double, 3 > dir;
             dir[0] = p[0]-center[0];
             dir[1] = p[1]-center[1];
             dir[2] = p[2]-center[2];
             dir = rot*dir;
             dir[0] += center[0]+tx;
             dir[1] += center[1]+ty;
             dir[2] += center[2]+tz;
             vtkIdType id = vtkNewPoints->InsertNextPoint(dir.data_block());
             container->GetPointIds()->InsertNextId(id);
         }
         vtkNewCells->InsertNextCell(container);
     }
 
     m_FiberPolyData = vtkSmartPointer<vtkPolyData>::New();
     m_FiberPolyData->SetPoints(vtkNewPoints);
     m_FiberPolyData->SetLines(vtkNewCells);
     UpdateColorCoding();
     UpdateFiberGeometry();
 }
 
 void mitk::FiberBundleX::RotateAroundAxis(double x, double y, double z)
 {
     x = x*M_PI/180;
     y = y*M_PI/180;
     z = z*M_PI/180;
 
     vnl_matrix_fixed< double, 3, 3 > rotX; rotX.set_identity();
     rotX[1][1] = cos(x);
     rotX[2][2] = rotX[1][1];
     rotX[1][2] = -sin(x);
     rotX[2][1] = -rotX[1][2];
 
     vnl_matrix_fixed< double, 3, 3 > rotY; rotY.set_identity();
     rotY[0][0] = cos(y);
     rotY[2][2] = rotY[0][0];
     rotY[0][2] = sin(y);
     rotY[2][0] = -rotY[0][2];
 
     vnl_matrix_fixed< double, 3, 3 > rotZ; rotZ.set_identity();
     rotZ[0][0] = cos(z);
     rotZ[1][1] = rotZ[0][0];
     rotZ[0][1] = -sin(z);
     rotZ[1][0] = -rotZ[0][1];
 
     mitk::BaseGeometry::Pointer geom = this->GetGeometry();
     mitk::Point3D center = geom->GetCenter();
 
     vtkSmartPointer<vtkPoints> vtkNewPoints = vtkSmartPointer<vtkPoints>::New();
     vtkSmartPointer<vtkCellArray> vtkNewCells = vtkSmartPointer<vtkCellArray>::New();
 
     for (int i=0; i<m_NumFibers; i++)
     {
         vtkCell* cell = m_FiberPolyData->GetCell(i);
         int numPoints = cell->GetNumberOfPoints();
         vtkPoints* points = cell->GetPoints();
 
         vtkSmartPointer<vtkPolyLine> container = vtkSmartPointer<vtkPolyLine>::New();
         for (int j=0; j<numPoints; j++)
         {
             double* p = points->GetPoint(j);
             vnl_vector_fixed< double, 3 > dir;
             dir[0] = p[0]-center[0];
             dir[1] = p[1]-center[1];
             dir[2] = p[2]-center[2];
             dir = rotZ*rotY*rotX*dir;
             dir[0] += center[0];
             dir[1] += center[1];
             dir[2] += center[2];
             vtkIdType id = vtkNewPoints->InsertNextPoint(dir.data_block());
             container->GetPointIds()->InsertNextId(id);
         }
         vtkNewCells->InsertNextCell(container);
     }
 
     m_FiberPolyData = vtkSmartPointer<vtkPolyData>::New();
     m_FiberPolyData->SetPoints(vtkNewPoints);
     m_FiberPolyData->SetLines(vtkNewCells);
     UpdateColorCoding();
     UpdateFiberGeometry();
 }
 
 void mitk::FiberBundleX::ScaleFibers(double x, double y, double z, bool subtractCenter)
 {
     MITK_INFO << "Scaling fibers";
     boost::progress_display disp(m_NumFibers);
 
     mitk::BaseGeometry* geom = this->GetGeometry();
     mitk::Point3D c = geom->GetCenter();
 
     vtkSmartPointer<vtkPoints> vtkNewPoints = vtkSmartPointer<vtkPoints>::New();
     vtkSmartPointer<vtkCellArray> vtkNewCells = vtkSmartPointer<vtkCellArray>::New();
 
     for (int i=0; i<m_NumFibers; i++)
     {
         ++disp ;
         vtkCell* cell = m_FiberPolyData->GetCell(i);
         int numPoints = cell->GetNumberOfPoints();
         vtkPoints* points = cell->GetPoints();
 
         vtkSmartPointer<vtkPolyLine> container = vtkSmartPointer<vtkPolyLine>::New();
         for (int j=0; j<numPoints; j++)
         {
             double* p = points->GetPoint(j);
             if (subtractCenter)
             {
                 p[0] -= c[0]; p[1] -= c[1]; p[2] -= c[2];
             }
             p[0] *= x;
             p[1] *= y;
             p[2] *= z;
             if (subtractCenter)
             {
                 p[0] += c[0]; p[1] += c[1]; p[2] += c[2];
             }
             vtkIdType id = vtkNewPoints->InsertNextPoint(p);
             container->GetPointIds()->InsertNextId(id);
         }
         vtkNewCells->InsertNextCell(container);
     }
 
     m_FiberPolyData = vtkSmartPointer<vtkPolyData>::New();
     m_FiberPolyData->SetPoints(vtkNewPoints);
     m_FiberPolyData->SetLines(vtkNewCells);
     UpdateColorCoding();
     UpdateFiberGeometry();
 }
 
 void mitk::FiberBundleX::TranslateFibers(double x, double y, double z)
 {
     vtkSmartPointer<vtkPoints> vtkNewPoints = vtkSmartPointer<vtkPoints>::New();
     vtkSmartPointer<vtkCellArray> vtkNewCells = vtkSmartPointer<vtkCellArray>::New();
 
     for (int i=0; i<m_NumFibers; i++)
     {
         vtkCell* cell = m_FiberPolyData->GetCell(i);
         int numPoints = cell->GetNumberOfPoints();
         vtkPoints* points = cell->GetPoints();
 
         vtkSmartPointer<vtkPolyLine> container = vtkSmartPointer<vtkPolyLine>::New();
         for (int j=0; j<numPoints; j++)
         {
             double* p = points->GetPoint(j);
             p[0] += x;
             p[1] += y;
             p[2] += z;
             vtkIdType id = vtkNewPoints->InsertNextPoint(p);
             container->GetPointIds()->InsertNextId(id);
         }
         vtkNewCells->InsertNextCell(container);
     }
 
     m_FiberPolyData = vtkSmartPointer<vtkPolyData>::New();
     m_FiberPolyData->SetPoints(vtkNewPoints);
     m_FiberPolyData->SetLines(vtkNewCells);
     UpdateColorCoding();
     UpdateFiberGeometry();
 }
 
 void mitk::FiberBundleX::MirrorFibers(unsigned int axis)
 {
     if (axis>2)
         return;
 
     MITK_INFO << "Mirroring fibers";
     boost::progress_display disp(m_NumFibers);
 
     vtkSmartPointer<vtkPoints> vtkNewPoints = vtkSmartPointer<vtkPoints>::New();
     vtkSmartPointer<vtkCellArray> vtkNewCells = vtkSmartPointer<vtkCellArray>::New();
 
     for (int i=0; i<m_NumFibers; i++)
     {
         ++disp;
         vtkCell* cell = m_FiberPolyData->GetCell(i);
         int numPoints = cell->GetNumberOfPoints();
         vtkPoints* points = cell->GetPoints();
 
         vtkSmartPointer<vtkPolyLine> container = vtkSmartPointer<vtkPolyLine>::New();
         for (int j=0; j<numPoints; j++)
         {
             double* p = points->GetPoint(j);
             p[axis] = -p[axis];
             vtkIdType id = vtkNewPoints->InsertNextPoint(p);
             container->GetPointIds()->InsertNextId(id);
         }
         vtkNewCells->InsertNextCell(container);
     }
 
     m_FiberPolyData = vtkSmartPointer<vtkPolyData>::New();
     m_FiberPolyData->SetPoints(vtkNewPoints);
     m_FiberPolyData->SetLines(vtkNewCells);
     UpdateColorCoding();
     UpdateFiberGeometry();
 }
 
 bool mitk::FiberBundleX::ApplyCurvatureThreshold(float minRadius, bool deleteFibers)
 {
     if (minRadius<0)
         return true;
 
     vtkSmartPointer<vtkPoints> vtkNewPoints = vtkSmartPointer<vtkPoints>::New();
     vtkSmartPointer<vtkCellArray> vtkNewCells = vtkSmartPointer<vtkCellArray>::New();
 
     MITK_INFO << "Applying curvature threshold";
     boost::progress_display disp(m_FiberPolyData->GetNumberOfCells());
     for (int i=0; i<m_FiberPolyData->GetNumberOfCells(); i++)
     {
         ++disp ;
         vtkCell* cell = m_FiberPolyData->GetCell(i);
         int numPoints = cell->GetNumberOfPoints();
         vtkPoints* points = cell->GetPoints();
 
         // calculate curvatures
         vtkSmartPointer<vtkPolyLine> container = vtkSmartPointer<vtkPolyLine>::New();
         for (int j=0; j<numPoints-2; j++)
         {
             double p1[3];
             points->GetPoint(j, p1);
             double p2[3];
             points->GetPoint(j+1, p2);
             double p3[3];
             points->GetPoint(j+2, p3);
 
             vnl_vector_fixed< float, 3 > v1, v2, v3;
 
             v1[0] = p2[0]-p1[0];
             v1[1] = p2[1]-p1[1];
             v1[2] = p2[2]-p1[2];
 
             v2[0] = p3[0]-p2[0];
             v2[1] = p3[1]-p2[1];
             v2[2] = p3[2]-p2[2];
 
             v3[0] = p1[0]-p3[0];
             v3[1] = p1[1]-p3[1];
             v3[2] = p1[2]-p3[2];
 
             float a = v1.magnitude();
             float b = v2.magnitude();
             float c = v3.magnitude();
             float r = a*b*c/std::sqrt((a+b+c)*(a+b-c)*(b+c-a)*(a-b+c)); // radius of triangle via Heron's formula (area of triangle)
 
             vtkIdType id = vtkNewPoints->InsertNextPoint(p1);
             container->GetPointIds()->InsertNextId(id);
 
             if (deleteFibers && r<minRadius)
                 break;
 
             if (r<minRadius)
             {
                 j += 2;
                 vtkNewCells->InsertNextCell(container);
                 container = vtkSmartPointer<vtkPolyLine>::New();
             }
             else if (j==numPoints-3)
             {
                 id = vtkNewPoints->InsertNextPoint(p2);
                 container->GetPointIds()->InsertNextId(id);
                 id = vtkNewPoints->InsertNextPoint(p3);
                 container->GetPointIds()->InsertNextId(id);
                 vtkNewCells->InsertNextCell(container);
             }
         }
     }
 
     if (vtkNewCells->GetNumberOfCells()<=0)
         return false;
 
     m_FiberPolyData = vtkSmartPointer<vtkPolyData>::New();
     m_FiberPolyData->SetPoints(vtkNewPoints);
     m_FiberPolyData->SetLines(vtkNewCells);
 
     UpdateColorCoding();
     UpdateFiberGeometry();
     return true;
 }
 
 bool mitk::FiberBundleX::RemoveShortFibers(float lengthInMM)
 {
     MITK_INFO << "Removing short fibers";
     if (lengthInMM<=0 || lengthInMM<m_MinFiberLength)
     {
         MITK_INFO << "No fibers shorter than " << lengthInMM << " mm found!";
         return true;
     }
 
     if (lengthInMM>m_MaxFiberLength)    // can't remove all fibers
     {
         MITK_WARN << "Process aborted. No fibers would be left!";
         return false;
     }
 
     vtkSmartPointer<vtkPoints> vtkNewPoints = vtkSmartPointer<vtkPoints>::New();
     vtkSmartPointer<vtkCellArray> vtkNewCells = vtkSmartPointer<vtkCellArray>::New();
     float min = m_MaxFiberLength;
 
     boost::progress_display disp(m_NumFibers);
     for (int i=0; i<m_NumFibers; i++)
     {
         ++disp;
         vtkCell* cell = m_FiberPolyData->GetCell(i);
         int numPoints = cell->GetNumberOfPoints();
         vtkPoints* points = cell->GetPoints();
 
         if (m_FiberLengths.at(i)>=lengthInMM)
         {
             vtkSmartPointer<vtkPolyLine> container = vtkSmartPointer<vtkPolyLine>::New();
             for (int j=0; j<numPoints; j++)
             {
                 double* p = points->GetPoint(j);
                 vtkIdType id = vtkNewPoints->InsertNextPoint(p);
                 container->GetPointIds()->InsertNextId(id);
             }
             vtkNewCells->InsertNextCell(container);
             if (m_FiberLengths.at(i)<min)
                 min = m_FiberLengths.at(i);
         }
     }
 
     if (vtkNewCells->GetNumberOfCells()<=0)
         return false;
 
     m_FiberPolyData = vtkSmartPointer<vtkPolyData>::New();
     m_FiberPolyData->SetPoints(vtkNewPoints);
     m_FiberPolyData->SetLines(vtkNewCells);
 
     UpdateColorCoding();
     UpdateFiberGeometry();
     return true;
 }
 
 bool mitk::FiberBundleX::RemoveLongFibers(float lengthInMM)
 {
     if (lengthInMM<=0 || lengthInMM>m_MaxFiberLength)
         return true;
 
     if (lengthInMM<m_MinFiberLength)    // can't remove all fibers
         return false;
 
     vtkSmartPointer<vtkPoints> vtkNewPoints = vtkSmartPointer<vtkPoints>::New();
     vtkSmartPointer<vtkCellArray> vtkNewCells = vtkSmartPointer<vtkCellArray>::New();
 
     MITK_INFO << "Removing long fibers";
     boost::progress_display disp(m_NumFibers);
     for (int i=0; i<m_NumFibers; i++)
     {
         ++disp;
         vtkCell* cell = m_FiberPolyData->GetCell(i);
         int numPoints = cell->GetNumberOfPoints();
         vtkPoints* points = cell->GetPoints();
 
         if (m_FiberLengths.at(i)<=lengthInMM)
         {
             vtkSmartPointer<vtkPolyLine> container = vtkSmartPointer<vtkPolyLine>::New();
             for (int j=0; j<numPoints; j++)
             {
                 double* p = points->GetPoint(j);
                 vtkIdType id = vtkNewPoints->InsertNextPoint(p);
                 container->GetPointIds()->InsertNextId(id);
             }
             vtkNewCells->InsertNextCell(container);
         }
     }
 
     if (vtkNewCells->GetNumberOfCells()<=0)
         return false;
 
     m_FiberPolyData = vtkSmartPointer<vtkPolyData>::New();
     m_FiberPolyData->SetPoints(vtkNewPoints);
     m_FiberPolyData->SetLines(vtkNewCells);
     UpdateColorCoding();
     UpdateFiberGeometry();
     return true;
 }
 
 void mitk::FiberBundleX::ResampleSpline(float pointDistance, double tension, double continuity, double bias )
 {
     if (pointDistance<=0)
         return;
 
     vtkSmartPointer<vtkPoints> vtkSmoothPoints = vtkSmartPointer<vtkPoints>::New(); //in smoothpoints the interpolated points representing a fiber are stored.
 
     //in vtkcells all polylines are stored, actually all id's of them are stored
     vtkSmartPointer<vtkCellArray> vtkSmoothCells = vtkSmartPointer<vtkCellArray>::New(); //cellcontainer for smoothed lines
     vtkIdType pointHelperCnt = 0;
 
     MITK_INFO << "Smoothing fibers";
     boost::progress_display disp(m_NumFibers);
     for (int i=0; i<m_NumFibers; i++)
     {
         ++disp;
         vtkCell* cell = m_FiberPolyData->GetCell(i);
         int numPoints = cell->GetNumberOfPoints();
         vtkPoints* points = cell->GetPoints();
 
         vtkSmartPointer<vtkPoints> newPoints = vtkSmartPointer<vtkPoints>::New();
         for (int j=0; j<numPoints; j++)
             newPoints->InsertNextPoint(points->GetPoint(j));
 
         float length = m_FiberLengths.at(i);
         int sampling = std::ceil(length/pointDistance);
 
         vtkSmartPointer<vtkKochanekSpline> xSpline = vtkSmartPointer<vtkKochanekSpline>::New();
         vtkSmartPointer<vtkKochanekSpline> ySpline = vtkSmartPointer<vtkKochanekSpline>::New();
         vtkSmartPointer<vtkKochanekSpline> zSpline = vtkSmartPointer<vtkKochanekSpline>::New();
         xSpline->SetDefaultBias(bias); xSpline->SetDefaultTension(tension); xSpline->SetDefaultContinuity(continuity);
         ySpline->SetDefaultBias(bias); ySpline->SetDefaultTension(tension); ySpline->SetDefaultContinuity(continuity);
         zSpline->SetDefaultBias(bias); zSpline->SetDefaultTension(tension); zSpline->SetDefaultContinuity(continuity);
 
         vtkSmartPointer<vtkParametricSpline> spline = vtkSmartPointer<vtkParametricSpline>::New();
         spline->SetXSpline(xSpline);
         spline->SetYSpline(ySpline);
         spline->SetZSpline(zSpline);
         spline->SetPoints(newPoints);
 
         vtkSmartPointer<vtkParametricFunctionSource> functionSource = vtkSmartPointer<vtkParametricFunctionSource>::New();
         functionSource->SetParametricFunction(spline);
         functionSource->SetUResolution(sampling);
         functionSource->SetVResolution(sampling);
         functionSource->SetWResolution(sampling);
         functionSource->Update();
 
         vtkPolyData* outputFunction = functionSource->GetOutput();
         vtkPoints* tmpSmoothPnts = outputFunction->GetPoints(); //smoothPoints of current fiber
 
         vtkSmartPointer<vtkPolyLine> smoothLine = vtkSmartPointer<vtkPolyLine>::New();
         smoothLine->GetPointIds()->SetNumberOfIds(tmpSmoothPnts->GetNumberOfPoints());
 
         for (int j=0; j<smoothLine->GetNumberOfPoints(); j++)
         {
             smoothLine->GetPointIds()->SetId(j, j+pointHelperCnt);
             vtkSmoothPoints->InsertNextPoint(tmpSmoothPnts->GetPoint(j));
         }
         vtkSmoothCells->InsertNextCell(smoothLine);
         pointHelperCnt += tmpSmoothPnts->GetNumberOfPoints();
     }
 
     m_FiberPolyData = vtkSmartPointer<vtkPolyData>::New();
     m_FiberPolyData->SetPoints(vtkSmoothPoints);
     m_FiberPolyData->SetLines(vtkSmoothCells);
     UpdateColorCoding();
     UpdateFiberGeometry();
     m_FiberSampling = 10/pointDistance;
 }
 
 void mitk::FiberBundleX::ResampleSpline(float pointDistance)
 {
     ResampleSpline(pointDistance, 0, 0, 0 );
 }
 
 unsigned long mitk::FiberBundleX::GetNumberOfPoints()
 {
     unsigned long points = 0;
     for (int i=0; i<m_FiberPolyData->GetNumberOfCells(); i++)
     {
         vtkCell* cell = m_FiberPolyData->GetCell(i);
         points += cell->GetNumberOfPoints();
     }
     return points;
 }
 
 void mitk::FiberBundleX::Compress(float error)
 {
     vtkSmartPointer<vtkPoints> vtkNewPoints = vtkSmartPointer<vtkPoints>::New();
     vtkSmartPointer<vtkCellArray> vtkNewCells = vtkSmartPointer<vtkCellArray>::New();
 
     MITK_INFO << "Compressing fibers";
     unsigned long numRemovedPoints = 0;
     boost::progress_display disp(m_FiberPolyData->GetNumberOfCells());
 
     for (int i=0; i<m_FiberPolyData->GetNumberOfCells(); i++)
     {
         ++disp;
         vtkCell* cell = m_FiberPolyData->GetCell(i);
         int numPoints = cell->GetNumberOfPoints();
         vtkPoints* points = cell->GetPoints();
 
         // calculate curvatures
         std::vector< int > removedPoints; removedPoints.resize(numPoints, 0);
         removedPoints[0]=-1; removedPoints[numPoints-1]=-1;
 
         vtkSmartPointer<vtkPolyLine> container = vtkSmartPointer<vtkPolyLine>::New();
 
         bool pointFound = true;
         while (pointFound)
         {
             pointFound = false;
             double minError = error;
             int removeIndex = -1;
 
             for (int j=0; j<numPoints; j++)
             {
                 if (removedPoints[j]==0)
                 {
                     double cand[3];
                     points->GetPoint(j, cand);
                     vnl_vector_fixed< double, 3 > candV;
                     candV[0]=cand[0]; candV[1]=cand[1]; candV[2]=cand[2];
 
                     int validP = -1;
                     vnl_vector_fixed< double, 3 > pred;
                     for (int k=j-1; k>=0; k--)
                         if (removedPoints[k]<=0)
                         {
                             double ref[3];
                             points->GetPoint(k, ref);
                             pred[0]=ref[0]; pred[1]=ref[1]; pred[2]=ref[2];
                             validP = k;
                             break;
                         }
                     int validS = -1;
                     vnl_vector_fixed< double, 3 > succ;
                     for (int k=j+1; k<numPoints; k++)
                         if (removedPoints[k]<=0)
                         {
                             double ref[3];
                             points->GetPoint(k, ref);
                             succ[0]=ref[0]; succ[1]=ref[1]; succ[2]=ref[2];
                             validS = k;
                             break;
                         }
 
                     if (validP>=0 && validS>=0)
                     {
                         double a = (candV-pred).magnitude();
                         double b = (candV-succ).magnitude();
                         double c = (pred-succ).magnitude();
                         double s=0.5*(a+b+c);
                         double hc=(2.0/c)*sqrt(fabs(s*(s-a)*(s-b)*(s-c)));
 
                         if (hc<minError)
                         {
                             removeIndex = j;
                             minError = hc;
                             pointFound = true;
                         }
                     }
                 }
             }
 
             if (pointFound)
             {
                 removedPoints[removeIndex] = 1;
                 numRemovedPoints++;
             }
         }
 
         for (int j=0; j<numPoints; j++)
         {
             if (removedPoints[j]<=0)
             {
                 double cand[3];
                 points->GetPoint(j, cand);
                 vtkIdType id = vtkNewPoints->InsertNextPoint(cand);
                 container->GetPointIds()->InsertNextId(id);
             }
         }
 
         vtkNewCells->InsertNextCell(container);
     }
 
     if (vtkNewCells->GetNumberOfCells()>0)
     {
         MITK_INFO << "Removed points: " << numRemovedPoints;
         m_FiberPolyData = vtkSmartPointer<vtkPolyData>::New();
         m_FiberPolyData->SetPoints(vtkNewPoints);
         m_FiberPolyData->SetLines(vtkNewCells);
 
         UpdateColorCoding();
         UpdateFiberGeometry();
     }
 }
 
-// Resample fiber to get equidistant points
-void mitk::FiberBundleX::ResampleLinear(float pointDistance)
-{
-    if (pointDistance<=0.00001)
-        return;
-
-    vtkSmartPointer<vtkPolyData> newPoly = vtkSmartPointer<vtkPolyData>::New();
-    vtkSmartPointer<vtkCellArray> newCellArray = vtkSmartPointer<vtkCellArray>::New();
-    vtkSmartPointer<vtkPoints>    newPoints = vtkSmartPointer<vtkPoints>::New();
-
-    int numberOfLines = m_NumFibers;
-
-    MITK_INFO << "Resampling fibers";
-    boost::progress_display disp(m_NumFibers);
-    for (int i=0; i<numberOfLines; i++)
-    {
-        ++disp;
-        vtkCell* cell = m_FiberPolyData->GetCell(i);
-        int numPoints = cell->GetNumberOfPoints();
-        vtkPoints* points = cell->GetPoints();
-
-        vtkSmartPointer<vtkPolyLine> container = vtkSmartPointer<vtkPolyLine>::New();
-
-        double* point = points->GetPoint(0);
-        vtkIdType pointId = newPoints->InsertNextPoint(point);
-        container->GetPointIds()->InsertNextId(pointId);
-
-        float dtau = 0;
-        int cur_p = 1;
-        itk::Vector<float,3> dR;
-        float normdR = 0;
-
-        for (;;)
-        {
-            while (dtau <= pointDistance && cur_p < numPoints)
-            {
-                itk::Vector<float,3> v1;
-                point = points->GetPoint(cur_p-1);
-                v1[0] = point[0];
-                v1[1] = point[1];
-                v1[2] = point[2];
-                itk::Vector<float,3> v2;
-                point = points->GetPoint(cur_p);
-                v2[0] = point[0];
-                v2[1] = point[1];
-                v2[2] = point[2];
-
-                dR  = v2 - v1;
-                normdR = std::sqrt(dR.GetSquaredNorm());
-                dtau += normdR;
-                cur_p++;
-            }
-
-            if (dtau >= pointDistance)
-            {
-                itk::Vector<float,3> v1;
-                point = points->GetPoint(cur_p-1);
-                v1[0] = point[0];
-                v1[1] = point[1];
-                v1[2] = point[2];
-
-                itk::Vector<float,3> v2 = v1 - dR*( (dtau-pointDistance)/normdR );
-                pointId = newPoints->InsertNextPoint(v2.GetDataPointer());
-                container->GetPointIds()->InsertNextId(pointId);
-            }
-            else
-            {
-                point = points->GetPoint(numPoints-1);
-                pointId = newPoints->InsertNextPoint(point);
-                container->GetPointIds()->InsertNextId(pointId);
-                break;
-            }
-            dtau = dtau-pointDistance;
-        }
-
-        newCellArray->InsertNextCell(container);
-    }
-
-    newPoly->SetPoints(newPoints);
-    newPoly->SetLines(newCellArray);
-    m_FiberPolyData = newPoly;
-    UpdateFiberGeometry();
-    UpdateColorCoding();
-    m_FiberSampling = 10/pointDistance;
-}
-
 // reapply selected colorcoding in case polydata structure has changed
 void mitk::FiberBundleX::UpdateColorCoding()
 {
     char* cc = GetCurrentColorCoding();
 
     if( strcmp (COLORCODING_ORIENTATION_BASED,cc) == 0 )
         DoColorCodingOrientationBased();
     else if( strcmp (COLORCODING_FA_BASED,cc) == 0 )
         DoColorCodingFaBased();
 }
 
 // reapply selected colorcoding in case polydata structure has changed
 bool mitk::FiberBundleX::Equals(mitk::FiberBundleX* fib, double eps)
 {
     if (fib==NULL)
     {
         MITK_INFO << "Reference bundle is NULL!";
         return false;
     }
 
     if (m_NumFibers!=fib->GetNumFibers())
     {
         MITK_INFO << "Unequal number of fibers!";
         MITK_INFO << m_NumFibers << " vs. " << fib->GetNumFibers();
         return false;
     }
 
     for (int i=0; i<m_NumFibers; i++)
     {
         vtkCell* cell = m_FiberPolyData->GetCell(i);
         int numPoints = cell->GetNumberOfPoints();
         vtkPoints* points = cell->GetPoints();
 
         vtkCell* cell2 = fib->GetFiberPolyData()->GetCell(i);
         int numPoints2 = cell2->GetNumberOfPoints();
         vtkPoints* points2 = cell2->GetPoints();
 
         if (numPoints2!=numPoints)
         {
             MITK_INFO << "Unequal number of points in fiber " << i << "!";
             MITK_INFO << numPoints2 << " vs. " << numPoints;
             return false;
         }
 
         for (int j=0; j<numPoints; j++)
         {
             double* p1 = points->GetPoint(j);
             double* p2 = points2->GetPoint(j);
             if (fabs(p1[0]-p2[0])>eps || fabs(p1[1]-p2[1])>eps || fabs(p1[2]-p2[2])>eps)
             {
                 MITK_INFO << "Unequal points in fiber " << i << " at position " << j << "!";
                 MITK_INFO << "p1: " << p1[0] << ", " << p1[1] << ", " << p1[2];
                 MITK_INFO << "p2: " << p2[0] << ", " << p2[1] << ", " << p2[2];
                 return false;
             }
         }
     }
 
     return true;
 }
 
 /* ESSENTIAL IMPLEMENTATION OF SUPERCLASS METHODS */
 void mitk::FiberBundleX::UpdateOutputInformation()
 {
 
 }
 void mitk::FiberBundleX::SetRequestedRegionToLargestPossibleRegion()
 {
 
 }
 bool mitk::FiberBundleX::RequestedRegionIsOutsideOfTheBufferedRegion()
 {
     return false;
 }
 bool mitk::FiberBundleX::VerifyRequestedRegion()
 {
     return true;
 }
 void mitk::FiberBundleX::SetRequestedRegion(const itk::DataObject* )
 {
 
 }
diff --git a/Modules/DiffusionImaging/FiberTracking/IODataStructures/FiberBundleX/mitkFiberBundleX.h b/Modules/DiffusionImaging/FiberTracking/IODataStructures/FiberBundleX/mitkFiberBundleX.h
index 1fec06084e..be5433ca32 100644
--- a/Modules/DiffusionImaging/FiberTracking/IODataStructures/FiberBundleX/mitkFiberBundleX.h
+++ b/Modules/DiffusionImaging/FiberTracking/IODataStructures/FiberBundleX/mitkFiberBundleX.h
@@ -1,176 +1,175 @@
 /*===================================================================
 
 The Medical Imaging Interaction Toolkit (MITK)
 
 Copyright (c) German Cancer Research Center,
 Division of Medical and Biological Informatics.
 All rights reserved.
 
 This software is distributed WITHOUT ANY WARRANTY; without
 even the implied warranty of MERCHANTABILITY or FITNESS FOR
 A PARTICULAR PURPOSE.
 
 See LICENSE.txt or http://www.mitk.org for details.
 
 ===================================================================*/
 
 
 #ifndef _MITK_FiberBundleX_H
 #define _MITK_FiberBundleX_H
 
 //includes for MITK datastructure
 #include <mitkBaseData.h>
 #include <MitkFiberTrackingExports.h>
 #include <mitkImage.h>
 
 
 //includes storing fiberdata
 #include <vtkSmartPointer.h>
 #include <vtkPolyData.h>
 #include <vtkPoints.h>
 #include <vtkDataSet.h>
 #include <vtkTransform.h>
 
 //#include <QStringList>
 
 #include <mitkPlanarFigure.h>
 #include <mitkPixelTypeTraits.h>
 #include <mitkPlanarFigureComposite.h>
 
 namespace mitk {
 
 /**
    * \brief Base Class for Fiber Bundles;   */
 class MitkFiberTracking_EXPORT FiberBundleX : public BaseData
 {
 public:
 
     typedef itk::Image<unsigned char, 3> ItkUcharImgType;
 
     // fiber colorcodings
     static const char* COLORCODING_ORIENTATION_BASED;
     static const char* COLORCODING_FA_BASED;
     static const char* COLORCODING_CUSTOM;
     static const char* FIBER_ID_ARRAY;
 
     virtual void UpdateOutputInformation();
     virtual void SetRequestedRegionToLargestPossibleRegion();
     virtual bool RequestedRegionIsOutsideOfTheBufferedRegion();
     virtual bool VerifyRequestedRegion();
     virtual void SetRequestedRegion(const itk::DataObject*);
 
     mitkClassMacro( FiberBundleX, BaseData )
     itkFactorylessNewMacro(Self)
     itkCloneMacro(Self)
     mitkNewMacro1Param(Self, vtkSmartPointer<vtkPolyData>) // custom constructor
 
     // colorcoding related methods
     void SetColorCoding(const char*);
     void SetFAMap(mitk::Image::Pointer);
     template <typename TPixel>
     void SetFAMap(const mitk::PixelType pixelType, mitk::Image::Pointer);
     void DoColorCodingOrientationBased();
     void DoColorCodingFaBased();
     void DoUseFaFiberOpacity();
     void ResetFiberOpacity();
 
     // fiber compression
     void Compress(float error = 0.0);
 
     // fiber resampling
-    void ResampleLinear(float pointDistance = 1);
     void ResampleSpline(float pointDistance=1);
     void ResampleSpline(float pointDistance, double tension, double continuity, double bias );
 
     bool RemoveShortFibers(float lengthInMM);
     bool RemoveLongFibers(float lengthInMM);
     bool ApplyCurvatureThreshold(float minRadius, bool deleteFibers);
     void MirrorFibers(unsigned int axis);
     void RotateAroundAxis(double x, double y, double z);
     void TranslateFibers(double x, double y, double z);
     void ScaleFibers(double x, double y, double z, bool subtractCenter=true);
     void TransformFibers(double rx, double ry, double rz, double tx, double ty, double tz);
     itk::Point<float, 3> TransformPoint(vnl_vector_fixed< double, 3 > point, double rx, double ry, double rz, double tx, double ty, double tz);
     itk::Matrix< double, 3, 3 > TransformMatrix(itk::Matrix< double, 3, 3 > m, double rx, double ry, double rz);
 
     // add/subtract fibers
     FiberBundleX::Pointer AddBundle(FiberBundleX* fib);
     FiberBundleX::Pointer SubtractBundle(FiberBundleX* fib);
 
     // fiber subset extraction
     FiberBundleX::Pointer           ExtractFiberSubset(BaseData* roi);
     std::vector<long>               ExtractFiberIdSubset(BaseData* roi);
     FiberBundleX::Pointer           ExtractFiberSubset(ItkUcharImgType* mask, bool anyPoint, bool invert=false);
     FiberBundleX::Pointer           RemoveFibersOutside(ItkUcharImgType* mask, bool invert=false);
 
     vtkSmartPointer<vtkPolyData>    GeneratePolyDataByIds( std::vector<long> ); // TODO: make protected
     void                            GenerateFiberIds(); // TODO: make protected
 
     // get/set data
     void SetFiberPolyData(vtkSmartPointer<vtkPolyData>, bool updateGeometry = true);
     vtkSmartPointer<vtkPolyData> GetFiberPolyData() const;
     std::vector< std::string > GetAvailableColorCodings();
     char* GetCurrentColorCoding();
     itkGetMacro( NumFibers, int)
     //itkGetMacro( FiberSampling, int)
     int GetNumFibers() const {return m_NumFibers;}
     itkGetMacro( MinFiberLength, float )
     itkGetMacro( MaxFiberLength, float )
     itkGetMacro( MeanFiberLength, float )
     itkGetMacro( MedianFiberLength, float )
     itkGetMacro( LengthStDev, float )
     itkGetMacro( UpdateTime2D, itk::TimeStamp )
     itkGetMacro( UpdateTime3D, itk::TimeStamp )
     void RequestUpdate2D(){ m_UpdateTime2D.Modified(); }
     void RequestUpdate3D(){ m_UpdateTime3D.Modified(); }
 
     unsigned long GetNumberOfPoints();
 
     // copy fiber bundle
     mitk::FiberBundleX::Pointer GetDeepCopy();
 
     // compare fiber bundles
     bool Equals(FiberBundleX* fib, double eps=0.0001);
 
     itkSetMacro( ReferenceGeometry, mitk::BaseGeometry::Pointer )
     itkGetConstMacro( ReferenceGeometry, mitk::BaseGeometry::Pointer )
 
 protected:
 
     FiberBundleX( vtkPolyData* fiberPolyData = NULL );
     virtual ~FiberBundleX();
 
     itk::Point<float, 3> GetItkPoint(double point[3]);
 
     // calculate geometry from fiber extent
     void UpdateFiberGeometry();
 
     // calculate colorcoding values according to m_CurrentColorCoding
     void UpdateColorCoding();
 
 private:
 
     // actual fiber container
     vtkSmartPointer<vtkPolyData>  m_FiberPolyData;
 
     // contains fiber ids
     vtkSmartPointer<vtkDataSet>   m_FiberIdDataSet;
 
     char* m_CurrentColorCoding;
     int   m_NumFibers;
 
     std::vector< float > m_FiberLengths;
     float   m_MinFiberLength;
     float   m_MaxFiberLength;
     float   m_MeanFiberLength;
     float   m_MedianFiberLength;
     float   m_LengthStDev;
     int     m_FiberSampling;
     itk::TimeStamp m_UpdateTime2D;
     itk::TimeStamp m_UpdateTime3D;
     mitk::BaseGeometry::Pointer m_ReferenceGeometry;
 };
 
 } // namespace mitk
 
 #endif /*  _MITK_FiberBundleX_H */
diff --git a/Modules/DiffusionImaging/FiberTracking/Testing/mitkFiberExtractionTest.cpp b/Modules/DiffusionImaging/FiberTracking/Testing/mitkFiberExtractionTest.cpp
index 66823a77b9..847be12cb8 100644
--- a/Modules/DiffusionImaging/FiberTracking/Testing/mitkFiberExtractionTest.cpp
+++ b/Modules/DiffusionImaging/FiberTracking/Testing/mitkFiberExtractionTest.cpp
@@ -1,105 +1,109 @@
 /*===================================================================
 
 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 <mitkTestingMacros.h>
 #include <mitkIOUtil.h>
 #include <mitkFiberBundleX.h>
 #include <mitkPlanarFigure.h>
 #include <mitkPlanarFigureComposite.h>
 #include <mitkImageCast.h>
 
 #include <vtkDebugLeaks.h>
 
 /**Documentation
  *  Test if fiber transfortaiom methods work correctly
  */
 int mitkFiberExtractionTest(int argc, char* argv[])
 {
     MITK_TEST_BEGIN("mitkFiberExtractionTest");
 
     /// \todo Fix VTK memory leaks. Bug 18097.
     vtkDebugLeaks::SetExitError(0);
 
     MITK_INFO << "argc: " << argc;
     MITK_TEST_CONDITION_REQUIRED(argc==13,"check for input data")
 
             try{
         mitk::FiberBundleX::Pointer groundTruthFibs = dynamic_cast<mitk::FiberBundleX*>(mitk::IOUtil::LoadDataNode(argv[1])->GetData());
         mitk::FiberBundleX::Pointer testFibs = dynamic_cast<mitk::FiberBundleX*>(mitk::IOUtil::LoadDataNode(argv[2])->GetData());
 
         // test planar figure based extraction
         mitk::PlanarFigure::Pointer pf1 = dynamic_cast<mitk::PlanarFigure*>(mitk::IOUtil::LoadDataNode(argv[3])->GetData());
         mitk::PlanarFigure::Pointer pf2 = dynamic_cast<mitk::PlanarFigure*>(mitk::IOUtil::LoadDataNode(argv[4])->GetData());
         mitk::PlanarFigure::Pointer pf3 = dynamic_cast<mitk::PlanarFigure*>(mitk::IOUtil::LoadDataNode(argv[5])->GetData());
 
         MITK_INFO << "TEST1";
 
         mitk::PlanarFigureComposite::Pointer pfc1 = mitk::PlanarFigureComposite::New();
         pfc1->setOperationType(mitk::PFCOMPOSITION_AND_OPERATION);
         pfc1->addPlanarFigure(dynamic_cast<mitk::BaseData*>(pf2.GetPointer()));
         pfc1->addPlanarFigure(dynamic_cast<mitk::BaseData*>(pf3.GetPointer()));
         MITK_INFO << "TEST2";
         mitk::PlanarFigureComposite::Pointer pfc2 = mitk::PlanarFigureComposite::New();
         pfc2->setOperationType(mitk::PFCOMPOSITION_OR_OPERATION);
         pfc2->addPlanarFigure(dynamic_cast<mitk::BaseData*>(pf1.GetPointer()));
         pfc2->addPlanarFigure(pfc1.GetPointer());
         MITK_INFO << "TEST3";
         mitk::FiberBundleX::Pointer extractedFibs = groundTruthFibs->ExtractFiberSubset(pfc2);
         MITK_INFO << "TEST4";
         MITK_TEST_CONDITION_REQUIRED(extractedFibs->Equals(testFibs),"check planar figure extraction")
 
                 MITK_INFO << "TEST5";
         // test subtraction and addition
         mitk::FiberBundleX::Pointer notExtractedFibs = groundTruthFibs->SubtractBundle(extractedFibs);
 
         MITK_INFO << argv[11];
         testFibs = dynamic_cast<mitk::FiberBundleX*>(mitk::IOUtil::LoadDataNode(argv[11])->GetData());
         MITK_TEST_CONDITION_REQUIRED(notExtractedFibs->Equals(testFibs),"check bundle subtraction")
 
         mitk::FiberBundleX::Pointer joinded = extractedFibs->AddBundle(notExtractedFibs);
         testFibs = dynamic_cast<mitk::FiberBundleX*>(mitk::IOUtil::LoadDataNode(argv[12])->GetData());
         MITK_TEST_CONDITION_REQUIRED(joinded->Equals(testFibs),"check bundle addition")
 
         // test binary image based extraction
         mitk::Image::Pointer mitkRoiImage = dynamic_cast<mitk::Image*>(mitk::IOUtil::LoadDataNode(argv[6])->GetData());
         typedef itk::Image< unsigned char, 3 >    itkUCharImageType;
         itkUCharImageType::Pointer itkRoiImage = itkUCharImageType::New();
         mitk::CastToItkImage(mitkRoiImage, itkRoiImage);
 
         mitk::FiberBundleX::Pointer inside = groundTruthFibs->RemoveFibersOutside(itkRoiImage, false);
+        mitk::IOUtil::SaveBaseData(inside, mitk::IOUtil::GetTempPath()+"inside.fib");
         mitk::FiberBundleX::Pointer outside = groundTruthFibs->RemoveFibersOutside(itkRoiImage, true);
+        mitk::IOUtil::SaveBaseData(outside, mitk::IOUtil::GetTempPath()+"outside.fib");
         mitk::FiberBundleX::Pointer passing = groundTruthFibs->ExtractFiberSubset(itkRoiImage, true);
+        mitk::IOUtil::SaveBaseData(passing, mitk::IOUtil::GetTempPath()+"passing.fib");
         mitk::FiberBundleX::Pointer ending = groundTruthFibs->ExtractFiberSubset(itkRoiImage, false);
+        mitk::IOUtil::SaveBaseData(ending, mitk::IOUtil::GetTempPath()+"ending.fib");
 
         testFibs = dynamic_cast<mitk::FiberBundleX*>(mitk::IOUtil::LoadDataNode(argv[7])->GetData());
         MITK_TEST_CONDITION_REQUIRED(inside->Equals(testFibs),"check inside mask extraction")
 
         testFibs = dynamic_cast<mitk::FiberBundleX*>(mitk::IOUtil::LoadDataNode(argv[8])->GetData());
         MITK_TEST_CONDITION_REQUIRED(outside->Equals(testFibs),"check outside mask extraction")
 
         testFibs = dynamic_cast<mitk::FiberBundleX*>(mitk::IOUtil::LoadDataNode(argv[9])->GetData());
         MITK_TEST_CONDITION_REQUIRED(passing->Equals(testFibs),"check passing mask extraction")
 
         testFibs = dynamic_cast<mitk::FiberBundleX*>(mitk::IOUtil::LoadDataNode(argv[10])->GetData());
         MITK_TEST_CONDITION_REQUIRED(ending->Equals(testFibs),"check ending in mask extraction")
     }
     catch(...) {
         return EXIT_FAILURE;
     }
 
     // always end with this!
     MITK_TEST_END();
 }
diff --git a/Modules/DiffusionImaging/FiberTracking/Testing/mitkFiberfoxAddArtifactsToDwiTest.cpp b/Modules/DiffusionImaging/FiberTracking/Testing/mitkFiberfoxAddArtifactsToDwiTest.cpp
index 54293a4b5c..5f991c3fc1 100644
--- a/Modules/DiffusionImaging/FiberTracking/Testing/mitkFiberfoxAddArtifactsToDwiTest.cpp
+++ b/Modules/DiffusionImaging/FiberTracking/Testing/mitkFiberfoxAddArtifactsToDwiTest.cpp
@@ -1,180 +1,182 @@
 /*===================================================================
 
 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 <mitkTestingMacros.h>
 #include <mitkIOUtil.h>
 #include <mitkFiberBundleX.h>
 #include <itkAddArtifactsToDwiImageFilter.h>
 #include <mitkFiberfoxParameters.h>
 #include <mitkStickModel.h>
 #include <mitkTensorModel.h>
 #include <mitkBallModel.h>
 #include <mitkDotModel.h>
 #include <mitkAstroStickModel.h>
 #include <mitkDiffusionImage.h>
 #include <itkTestingComparisonImageFilter.h>
 #include <itkImageRegionConstIterator.h>
 #include <mitkRicianNoiseModel.h>
 #include <mitkChiSquareNoiseModel.h>
 #include <mitkTestFixture.h>
 
 /**Documentation
  * Test the Fiberfox simulation functions (diffusion weighted image -> diffusion weighted image)
  */
 class mitkFiberfoxAddArtifactsToDwiTestSuite : public mitk::TestFixture
 {
 
     CPPUNIT_TEST_SUITE(mitkFiberfoxAddArtifactsToDwiTestSuite);
     MITK_TEST(Spikes);
     MITK_TEST(GibbsRinging);
     MITK_TEST(Ghost);
     MITK_TEST(Aliasing);
     MITK_TEST(Eddy);
     MITK_TEST(RicianNoise);
     MITK_TEST(ChiSquareNoise);
     MITK_TEST(Distortions);
     CPPUNIT_TEST_SUITE_END();
 
 private:
 
     mitk::DiffusionImage<short>::Pointer m_InputDwi;
     FiberfoxParameters<short> m_Parameters;
 
 public:
 
     void setUp()
     {
         // reference files
         m_InputDwi = dynamic_cast<mitk::DiffusionImage<short>*>(mitk::IOUtil::LoadDataNode(GetTestDataFilePath("DiffusionImaging/Fiberfox/StickBall_RELAX.dwi"))->GetData());
 
         // parameter setup
         m_Parameters = FiberfoxParameters<short>();
         m_Parameters.m_SignalGen.m_ImageRegion = m_InputDwi->GetVectorImage()->GetLargestPossibleRegion();
         m_Parameters.m_SignalGen.m_ImageSpacing = m_InputDwi->GetVectorImage()->GetSpacing();
         m_Parameters.m_SignalGen.m_ImageOrigin = m_InputDwi->GetVectorImage()->GetOrigin();
         m_Parameters.m_SignalGen.m_ImageDirection = m_InputDwi->GetVectorImage()->GetDirection();
         m_Parameters.m_SignalGen.m_Bvalue = m_InputDwi->GetReferenceBValue();
         m_Parameters.m_SignalGen.SetGradienDirections(m_InputDwi->GetDirections());
     }
 
     bool CompareDwi(itk::VectorImage< short, 3 >* dwi1, itk::VectorImage< short, 3 >* dwi2)
     {
         typedef itk::VectorImage< short, 3 > DwiImageType;
         try{
             itk::ImageRegionIterator< DwiImageType > it1(dwi1, dwi1->GetLargestPossibleRegion());
             itk::ImageRegionIterator< DwiImageType > it2(dwi2, dwi2->GetLargestPossibleRegion());
             while(!it1.IsAtEnd())
             {
                 if (it1.Get()!=it2.Get())
                     return false;
                 ++it1;
                 ++it2;
             }
         }
         catch(...)
         {
             return false;
         }
         return true;
     }
 
     void StartSimulation(string testFileName)
     {
         mitk::DiffusionImage<short>::Pointer refImage = NULL;
         if (!testFileName.empty())
             CPPUNIT_ASSERT(refImage = dynamic_cast<mitk::DiffusionImage<short>*>(mitk::IOUtil::LoadDataNode(testFileName)->GetData()));
 
         itk::AddArtifactsToDwiImageFilter< short >::Pointer artifactsToDwiFilter = itk::AddArtifactsToDwiImageFilter< short >::New();
         artifactsToDwiFilter->SetUseConstantRandSeed(true);
         artifactsToDwiFilter->SetInput(m_InputDwi->GetVectorImage());
         artifactsToDwiFilter->SetParameters(m_Parameters);
         CPPUNIT_ASSERT_NO_THROW(artifactsToDwiFilter->Update());
 
         mitk::DiffusionImage<short>::Pointer testImage = mitk::DiffusionImage<short>::New();
         testImage->SetVectorImage( artifactsToDwiFilter->GetOutput() );
         testImage->SetReferenceBValue( m_Parameters.m_SignalGen.m_Bvalue);
         testImage->SetDirections( m_Parameters.m_SignalGen.GetGradientDirections());
         testImage->InitializeFromVectorImage();
 
         if (refImage.IsNotNull())
         {
+            if (!CompareDwi(testImage->GetVectorImage(), refImage->GetVectorImage()))
+                mitk::IOUtil::SaveBaseData(testImage, mitk::IOUtil::GetTempPath()+"testImage.dwi");
             CPPUNIT_ASSERT_MESSAGE(testFileName, CompareDwi(testImage->GetVectorImage(), refImage->GetVectorImage()));
         }
     }
 
     void Spikes()
     {
         m_Parameters.m_SignalGen.m_Spikes = 5;
         m_Parameters.m_SignalGen.m_SpikeAmplitude = 1;
         StartSimulation( GetTestDataFilePath("DiffusionImaging/Fiberfox/spikes2.dwi") );
     }
 
     void GibbsRinging()
     {
         m_Parameters.m_SignalGen.m_DoAddGibbsRinging = true;
         StartSimulation( GetTestDataFilePath("DiffusionImaging/Fiberfox/gibbsringing2.dwi") );
     }
 
     void Ghost()
     {
         m_Parameters.m_SignalGen.m_KspaceLineOffset = 0.25;
         StartSimulation( GetTestDataFilePath("DiffusionImaging/Fiberfox/ghost2.dwi") );
     }
 
     void Aliasing()
     {
         m_Parameters.m_SignalGen.m_CroppingFactor = 0.4;
         StartSimulation( GetTestDataFilePath("DiffusionImaging/Fiberfox/aliasing2.dwi") );
     }
 
     void Eddy()
     {
         m_Parameters.m_SignalGen.m_EddyStrength = 0.05;
         StartSimulation( GetTestDataFilePath("DiffusionImaging/Fiberfox/eddy2.dwi") );
     }
 
     void RicianNoise()
     {
         mitk::RicianNoiseModel<short>* ricianNoiseModel = new mitk::RicianNoiseModel<short>();
         ricianNoiseModel->SetNoiseVariance(1000000);
         ricianNoiseModel->SetSeed(0);
         m_Parameters.m_NoiseModel = ricianNoiseModel;
         StartSimulation( GetTestDataFilePath("DiffusionImaging/Fiberfox/riciannoise2.dwi") );
         delete  m_Parameters.m_NoiseModel;
     }
 
     void ChiSquareNoise()
     {
         mitk::ChiSquareNoiseModel<short>* chiSquareNoiseModel = new mitk::ChiSquareNoiseModel<short>();
         chiSquareNoiseModel->SetNoiseVariance(1000000);
         chiSquareNoiseModel->SetSeed(0);
         m_Parameters.m_NoiseModel = chiSquareNoiseModel;
         StartSimulation( GetTestDataFilePath("DiffusionImaging/Fiberfox/chisquarenoise2.dwi") );
         delete  m_Parameters.m_NoiseModel;
     }
 
     void Distortions()
     {
         mitk::Image::Pointer mitkFMap = dynamic_cast<mitk::Image*>(mitk::IOUtil::LoadDataNode( GetTestDataFilePath("DiffusionImaging/Fiberfox/Fieldmap.nrrd") )->GetData());
         typedef itk::Image<double, 3> ItkDoubleImgType;
         ItkDoubleImgType::Pointer fMap = ItkDoubleImgType::New();
         mitk::CastToItkImage(mitkFMap, fMap);
         m_Parameters.m_SignalGen.m_FrequencyMap = fMap;
         StartSimulation( GetTestDataFilePath("DiffusionImaging/Fiberfox/distortions2.dwi") );
     }
 };
 
 MITK_TEST_SUITE_REGISTRATION(mitkFiberfoxAddArtifactsToDwi)
diff --git a/Modules/DiffusionImaging/FiberTracking/Testing/mitkLocalFiberPlausibilityTest.cpp b/Modules/DiffusionImaging/FiberTracking/Testing/mitkLocalFiberPlausibilityTest.cpp
index d507c48488..9b49819365 100755
--- a/Modules/DiffusionImaging/FiberTracking/Testing/mitkLocalFiberPlausibilityTest.cpp
+++ b/Modules/DiffusionImaging/FiberTracking/Testing/mitkLocalFiberPlausibilityTest.cpp
@@ -1,190 +1,167 @@
 /*===================================================================
 
 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 <mitkBaseDataIOFactory.h>
 #include <mitkBaseData.h>
 #include <mitkImageCast.h>
 #include <mitkImageToItk.h>
 #include <itkEvaluateDirectionImagesFilter.h>
 #include <itkTractsToVectorImageFilter.h>
 #include <usAny.h>
 #include <itkImageFileWriter.h>
 #include <mitkIOUtil.h>
 #include <boost/lexical_cast.hpp>
 #include <iostream>
 #include <fstream>
 #include <itksys/SystemTools.hxx>
 #include <mitkTestingMacros.h>
 #include <mitkCompareImageDataFilter.h>
 #include <mitkCoreObjectFactory.h>
 
 #define _USE_MATH_DEFINES
 #include <math.h>
 
 using namespace std;
 
 int mitkLocalFiberPlausibilityTest(int argc, char* argv[])
 {
     MITK_TEST_BEGIN("mitkLocalFiberPlausibilityTest");
     MITK_TEST_CONDITION_REQUIRED(argc==8,"check for input data")
 
             string fibFile = argv[1];
     vector< string > referenceImages;
     referenceImages.push_back(argv[2]);
     referenceImages.push_back(argv[3]);
     string LDFP_ERROR_IMAGE = argv[4];
     string LDFP_NUM_DIRECTIONS = argv[5];
     string LDFP_VECTOR_FIELD = argv[6];
     string LDFP_ERROR_IMAGE_IGNORE = argv[7];
 
     float angularThreshold = 25;
 
     try
     {
         typedef itk::Image<unsigned char, 3>                                    ItkUcharImgType;
         typedef itk::Image< itk::Vector< float, 3>, 3 >                         ItkDirectionImage3DType;
         typedef itk::VectorContainer< unsigned int, ItkDirectionImage3DType::Pointer >   ItkDirectionImageContainerType;
         typedef itk::EvaluateDirectionImagesFilter< float >                     EvaluationFilterType;
 
         // load fiber bundle
         mitk::FiberBundleX::Pointer inputTractogram = dynamic_cast<mitk::FiberBundleX*>(mitk::IOUtil::LoadDataNode(fibFile)->GetData());
 
         // load reference directions
         ItkDirectionImageContainerType::Pointer referenceImageContainer = ItkDirectionImageContainerType::New();
         for (unsigned int i=0; i<referenceImages.size(); i++)
         {
             try
             {
                 mitk::Image::Pointer img = dynamic_cast<mitk::Image*>(mitk::IOUtil::LoadDataNode(referenceImages.at(i))->GetData());
                 typedef mitk::ImageToItk< ItkDirectionImage3DType > CasterType;
                 CasterType::Pointer caster = CasterType::New();
                 caster->SetInput(img);
                 caster->Update();
                 ItkDirectionImage3DType::Pointer itkImg = caster->GetOutput();
                 referenceImageContainer->InsertElement(referenceImageContainer->Size(),itkImg);
             }
             catch(...){ MITK_INFO << "could not load: " << referenceImages.at(i); }
         }
 
         ItkUcharImgType::Pointer itkMaskImage = ItkUcharImgType::New();
         ItkDirectionImage3DType::Pointer dirImg = referenceImageContainer->GetElement(0);
         itkMaskImage->SetSpacing( dirImg->GetSpacing() );
         itkMaskImage->SetOrigin( dirImg->GetOrigin() );
         itkMaskImage->SetDirection( dirImg->GetDirection() );
         itkMaskImage->SetLargestPossibleRegion( dirImg->GetLargestPossibleRegion() );
         itkMaskImage->SetBufferedRegion( dirImg->GetLargestPossibleRegion() );
         itkMaskImage->SetRequestedRegion( dirImg->GetLargestPossibleRegion() );
         itkMaskImage->Allocate();
         itkMaskImage->FillBuffer(1);
 
         // extract directions from fiber bundle
         itk::TractsToVectorImageFilter<float>::Pointer fOdfFilter = itk::TractsToVectorImageFilter<float>::New();
         fOdfFilter->SetFiberBundle(inputTractogram);
         fOdfFilter->SetMaskImage(itkMaskImage);
         fOdfFilter->SetAngularThreshold(cos(angularThreshold*M_PI/180));
         fOdfFilter->SetNormalizeVectors(true);
         //fOdfFilter->SetMaxNumDirections(1);
         fOdfFilter->SetSizeThreshold(0.0);
 
         fOdfFilter->SetUseWorkingCopy(false);
         fOdfFilter->SetNumberOfThreads(1);
         fOdfFilter->Update();
         ItkDirectionImageContainerType::Pointer directionImageContainer = fOdfFilter->GetDirectionImageContainer();
 
         // Get directions and num directions image
         ItkUcharImgType::Pointer numDirImage = fOdfFilter->GetNumDirectionsImage();
         mitk::Image::Pointer mitkNumDirImage = mitk::Image::New();
         mitkNumDirImage->InitializeByItk( numDirImage.GetPointer() );
         mitkNumDirImage->SetVolume( numDirImage->GetBufferPointer() );
         mitk::FiberBundleX::Pointer testDirections = fOdfFilter->GetOutputFiberBundle();
 
         // evaluate directions with missing directions
         EvaluationFilterType::Pointer evaluationFilter = EvaluationFilterType::New();
         evaluationFilter->SetImageSet(directionImageContainer);
         evaluationFilter->SetReferenceImageSet(referenceImageContainer);
         evaluationFilter->SetMaskImage(itkMaskImage);
         evaluationFilter->SetIgnoreMissingDirections(false);
         evaluationFilter->Update();
 
         EvaluationFilterType::OutputImageType::Pointer angularErrorImage = evaluationFilter->GetOutput(0);
         mitk::Image::Pointer mitkAngularErrorImage = mitk::Image::New();
         mitkAngularErrorImage->InitializeByItk( angularErrorImage.GetPointer() );
         mitkAngularErrorImage->SetVolume( angularErrorImage->GetBufferPointer() );
 
         // evaluate directions without missing directions
         evaluationFilter->SetIgnoreMissingDirections(true);
         evaluationFilter->Update();
 
         EvaluationFilterType::OutputImageType::Pointer angularErrorImageIgnore = evaluationFilter->GetOutput(0);
         mitk::Image::Pointer mitkAngularErrorImageIgnore = mitk::Image::New();
         mitkAngularErrorImageIgnore->InitializeByItk( angularErrorImageIgnore.GetPointer() );
         mitkAngularErrorImageIgnore->SetVolume( angularErrorImageIgnore->GetBufferPointer() );
 
         mitk::Image::Pointer gtAngularErrorImageIgnore = dynamic_cast<mitk::Image*>(mitk::IOUtil::LoadDataNode(LDFP_ERROR_IMAGE_IGNORE)->GetData());
         mitk::Image::Pointer gtAngularErrorImage = dynamic_cast<mitk::Image*>(mitk::IOUtil::LoadDataNode(LDFP_ERROR_IMAGE)->GetData());
         mitk::Image::Pointer gtNumTestDirImage = dynamic_cast<mitk::Image*>(mitk::IOUtil::LoadDataNode(LDFP_NUM_DIRECTIONS)->GetData());
         mitk::FiberBundleX::Pointer gtTestDirections = dynamic_cast<mitk::FiberBundleX*>(mitk::IOUtil::LoadDataNode(LDFP_VECTOR_FIELD)->GetData());
 
-//        if (!testDirections->Equals(gtTestDirections))
-//        {
-//            MITK_INFO << "SAVING FILES TO " << mitk::IOUtil::GetTempPath();
-//            std::string out1 = mitk::IOUtil::GetTempPath().append("test.nrrd");
-//            std::string out2 = mitk::IOUtil::GetTempPath().append("reference.nrrd");
-
-//            mitk::CoreObjectFactory::FileWriterList fileWriters = mitk::CoreObjectFactory::GetInstance()->GetFileWriters();
-//            for (mitk::CoreObjectFactory::FileWriterList::iterator it = fileWriters.begin() ; it != fileWriters.end() ; ++it)
-//            {
-//                if ( (*it)->CanWriteBaseDataType(testDirections.GetPointer()) ) {
-//                    (*it)->SetFileName( (mitk::IOUtil::GetTempPath()+"test.fib").c_str() );
-//                    (*it)->DoWrite( testDirections.GetPointer() );
-//                }
-//            }
-
-//            for (mitk::CoreObjectFactory::FileWriterList::iterator it = fileWriters.begin() ; it != fileWriters.end() ; ++it)
-//            {
-//                if ( (*it)->CanWriteBaseDataType(gtTestDirections.GetPointer()) ) {
-//                    (*it)->SetFileName( "/local/gt.fib" );
-//                    (*it)->DoWrite( gtTestDirections.GetPointer() );
-//                }
-//            }
-
-//            mitk::IOUtil::SaveBaseData(mitkNumDirImage, mitk::IOUtil::GetTempPath()+"testImage.nrrd");
-//            mitk::IOUtil::SaveBaseData(gtNumTestDirImage, mitk::IOUtil::GetTempPath()+"refImage.nrrd");
-//            return EXIT_FAILURE;
-//        }
+//        mitk::IOUtil::SaveBaseData(mitkAngularErrorImageIgnore, mitk::IOUtil::GetTempPath()+"mitkAngularErrorImageIgnore.nrrd");
+//        mitk::IOUtil::SaveBaseData(mitkAngularErrorImage, mitk::IOUtil::GetTempPath()+"mitkAngularErrorImage.nrrd");
+//        mitk::IOUtil::SaveBaseData(mitkNumDirImage, mitk::IOUtil::GetTempPath()+"mitkNumDirImage.nrrd");
+//        mitk::IOUtil::SaveBaseData(testDirections, mitk::IOUtil::GetTempPath()+"testDirections.fib");
 
         MITK_TEST_CONDITION_REQUIRED(mitk::Equal(gtAngularErrorImageIgnore, mitkAngularErrorImageIgnore, 0.01, true), "Check if error images are equal (ignored missing directions).");
         MITK_TEST_CONDITION_REQUIRED(mitk::Equal(gtAngularErrorImage, mitkAngularErrorImage, 0.01, true), "Check if error images are equal.");
         MITK_TEST_CONDITION_REQUIRED(testDirections->Equals(gtTestDirections), "Check if vector fields are equal.");
         MITK_TEST_CONDITION_REQUIRED(mitk::Equal(gtNumTestDirImage, mitkNumDirImage, 0.1, true), "Check if num direction images are equal.");
     }
     catch (itk::ExceptionObject e)
     {
         MITK_INFO << e;
         return EXIT_FAILURE;
     }
     catch (std::exception e)
     {
         MITK_INFO << e.what();
         return EXIT_FAILURE;
     }
     catch (...)
     {
         MITK_INFO << "ERROR!?!";
         return EXIT_FAILURE;
     }
     MITK_TEST_END();
 }
diff --git a/Modules/DiffusionImaging/MiniApps/FiberProcessing.cpp b/Modules/DiffusionImaging/MiniApps/FiberProcessing.cpp
index a0534029f5..0b2ea4d085 100644
--- a/Modules/DiffusionImaging/MiniApps/FiberProcessing.cpp
+++ b/Modules/DiffusionImaging/MiniApps/FiberProcessing.cpp
@@ -1,218 +1,210 @@
 /*===================================================================
 
 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 "MiniAppManager.h"
 
 #include <vector>
 #include <iostream>
 #include <fstream>
 #include <algorithm>
 #include <string>
 
 #include <itkImageFileWriter.h>
 #include <itkMetaDataObject.h>
 #include <itkVectorImage.h>
 
 #include <mitkBaseDataIOFactory.h>
 #include <mitkBaseData.h>
 #include <mitkFiberBundleX.h>
 #include "ctkCommandLineParser.h"
 #include <boost/lexical_cast.hpp>
 #include <mitkCoreObjectFactory.h>
 #include <mitkIOUtil.h>
 
 
 mitk::FiberBundleX::Pointer LoadFib(std::string filename)
 {
     const std::string s1="", s2="";
     std::vector<mitk::BaseData::Pointer> fibInfile = mitk::BaseDataIO::LoadBaseDataFromFile( filename, s1, s2, false );
     if( fibInfile.empty() )
         MITK_INFO << "File " << filename << " could not be read!";
 
     mitk::BaseData::Pointer baseData = fibInfile.at(0);
     return dynamic_cast<mitk::FiberBundleX*>(baseData.GetPointer());
 }
 
 int FiberProcessing(int argc, char* argv[])
 {
     MITK_INFO << "FiberProcessing";
     ctkCommandLineParser parser;
 
     parser.setTitle("Fiber Processing");
     parser.setCategory("Fiber Tracking and Processing Methods");
     parser.setDescription("");
     parser.setContributor("MBI");
 
     parser.setArgumentPrefix("--", "-");
     parser.addArgument("input", "i", ctkCommandLineParser::InputFile, "Input:", "input fiber bundle (.fib)", us::Any(), false);
     parser.addArgument("outFile", "o", ctkCommandLineParser::OutputFile, "Output:", "output fiber bundle (.fib)", us::Any(), false);
 
-    parser.addArgument("resample", "r", ctkCommandLineParser::Float, "Linear resampling:", "Linearly resample fiber with the given point distance (in mm)");
     parser.addArgument("smooth", "s", ctkCommandLineParser::Float, "Spline resampling:", "Resample fiber using splines with the given point distance (in mm)");
     parser.addArgument("compress", "c", ctkCommandLineParser::Float, "Compress:", "Compress fiber using the given error threshold (in mm)");
     parser.addArgument("minLength", "l", ctkCommandLineParser::Float, "Minimum length:", "Minimum fiber length (in mm)");
     parser.addArgument("maxLength", "m", ctkCommandLineParser::Float, "Maximum length:", "Maximum fiber length (in mm)");
     parser.addArgument("minCurv", "a", ctkCommandLineParser::Float, "Minimum curvature radius:", "Minimum curvature radius (in mm)");
     parser.addArgument("mirror", "p", ctkCommandLineParser::Int, "Invert coordinates:", "Invert fiber coordinates XYZ (e.g. 010 to invert y-coordinate of each fiber point)");
 
     parser.addArgument("rotate-x", "rx", ctkCommandLineParser::Float, "Rotate x-axis:", "Rotate around x-axis (if copy is given the copy is rotated, in deg)");
     parser.addArgument("rotate-y", "ry", ctkCommandLineParser::Float, "Rotate y-axis:", "Rotate around y-axis (if copy is given the copy is rotated, in deg)");
     parser.addArgument("rotate-z", "rz", ctkCommandLineParser::Float, "Rotate z-axis:", "Rotate around z-axis (if copy is given the copy is rotated, in deg)");
 
     parser.addArgument("scale-x", "sx", ctkCommandLineParser::Float, "Scale x-axis:", "Scale in direction of x-axis (if copy is given the copy is scaled)");
     parser.addArgument("scale-y", "sy", ctkCommandLineParser::Float, "Scale y-axis:", "Scale in direction of y-axis (if copy is given the copy is scaled)");
     parser.addArgument("scale-z", "sz", ctkCommandLineParser::Float, "Scale z-axis", "Scale in direction of z-axis (if copy is given the copy is scaled)");
 
     parser.addArgument("translate-x", "tx", ctkCommandLineParser::Float, "Translate x-axis:", "Translate in direction of x-axis (if copy is given the copy is translated, in mm)");
     parser.addArgument("translate-y", "ty", ctkCommandLineParser::Float, "Translate y-axis:", "Translate in direction of y-axis (if copy is given the copy is translated, in mm)");
     parser.addArgument("translate-z", "tz", ctkCommandLineParser::Float, "Translate z-axis:", "Translate in direction of z-axis (if copy is given the copy is translated, in mm)");
 
 
     map<string, us::Any> parsedArgs = parser.parseArguments(argc, argv);
     if (parsedArgs.size()==0)
         return EXIT_FAILURE;
 
-    float pointDist = -1;
-    if (parsedArgs.count("resample"))
-        pointDist = us::any_cast<float>(parsedArgs["resample"]);
-
     float smoothDist = -1;
     if (parsedArgs.count("smooth"))
         smoothDist = us::any_cast<float>(parsedArgs["smooth"]);
 
     float compress = -1;
     if (parsedArgs.count("compress"))
         compress = us::any_cast<float>(parsedArgs["compress"]);
 
     float minFiberLength = -1;
     if (parsedArgs.count("minLength"))
         minFiberLength = us::any_cast<float>(parsedArgs["minLength"]);
 
     float maxFiberLength = -1;
     if (parsedArgs.count("maxLength"))
         maxFiberLength = us::any_cast<float>(parsedArgs["maxLength"]);
 
     float curvThres = -1;
     if (parsedArgs.count("minCurv"))
         curvThres = us::any_cast<float>(parsedArgs["minCurv"]);
 
     int axis = 0;
     if (parsedArgs.count("mirror"))
         axis = us::any_cast<int>(parsedArgs["mirror"]);
 
     float rotateX = 0;
     if (parsedArgs.count("rotate-x"))
         rotateX = us::any_cast<float>(parsedArgs["rotate-x"]);
 
     float rotateY = 0;
     if (parsedArgs.count("rotate-y"))
         rotateY = us::any_cast<float>(parsedArgs["rotate-y"]);
 
     float rotateZ = 0;
     if (parsedArgs.count("rotate-z"))
         rotateZ = us::any_cast<float>(parsedArgs["rotate-z"]);
 
     float scaleX = 0;
     if (parsedArgs.count("scale-x"))
         scaleX = us::any_cast<float>(parsedArgs["scale-x"]);
 
     float scaleY = 0;
     if (parsedArgs.count("scale-y"))
         scaleY = us::any_cast<float>(parsedArgs["scale-y"]);
 
     float scaleZ = 0;
     if (parsedArgs.count("scale-z"))
         scaleZ = us::any_cast<float>(parsedArgs["scale-z"]);
 
     float translateX = 0;
     if (parsedArgs.count("translate-x"))
         translateX = us::any_cast<float>(parsedArgs["translate-x"]);
 
     float translateY = 0;
     if (parsedArgs.count("translate-y"))
         translateY = us::any_cast<float>(parsedArgs["translate-y"]);
 
     float translateZ = 0;
     if (parsedArgs.count("translate-z"))
         translateZ = us::any_cast<float>(parsedArgs["translate-z"]);
 
 
     string inFileName = us::any_cast<string>(parsedArgs["input"]);
     string outFileName = us::any_cast<string>(parsedArgs["outFile"]);
 
     try
     {
         mitk::FiberBundleX::Pointer fib = LoadFib(inFileName);
 
         if (minFiberLength>0)
             fib->RemoveShortFibers(minFiberLength);
 
         if (maxFiberLength>0)
             fib->RemoveLongFibers(maxFiberLength);
 
         if (curvThres>0)
             fib->ApplyCurvatureThreshold(curvThres, false);
 
-        if (pointDist>0)
-            fib->ResampleLinear(pointDist);
-
         if (smoothDist>0)
             fib->ResampleSpline(smoothDist);
 
         if (compress>0)
             fib->Compress(compress);
 
         if (axis/100==1)
             fib->MirrorFibers(0);
 
         if ((axis%100)/10==1)
             fib->MirrorFibers(1);
 
         if (axis%10==1)
             fib->MirrorFibers(2);
 
 
         if (rotateX > 0 || rotateY > 0 || rotateZ > 0){
             MITK_INFO << "Rotate " << rotateX << " " << rotateY << " " << rotateZ;
             fib->RotateAroundAxis(rotateX, rotateY, rotateZ);
         }
         if (translateX > 0 || translateY > 0 || translateZ > 0){
             fib->TranslateFibers(translateX, translateY, translateZ);
         }
         if (scaleX > 0 || scaleY > 0 || scaleZ > 0)
             fib->ScaleFibers(scaleX, scaleY, scaleZ);
 
         mitk::IOUtil::SaveBaseData(fib.GetPointer(), outFileName );
 
     }
     catch (itk::ExceptionObject e)
     {
         MITK_INFO << e;
         return EXIT_FAILURE;
     }
     catch (std::exception e)
     {
         MITK_INFO << e.what();
         return EXIT_FAILURE;
     }
     catch (...)
     {
         MITK_INFO << "ERROR!?!";
         return EXIT_FAILURE;
     }
     return EXIT_SUCCESS;
 }
 RegisterDiffusionMiniApp(FiberProcessing);