diff --git a/Modules/DiffusionImaging/FiberTracking/IODataStructures/FiberBundleX/mitkFiberBundleX.cpp b/Modules/DiffusionImaging/FiberTracking/IODataStructures/FiberBundleX/mitkFiberBundleX.cpp
index a32ca9c194..33d2b62952 100755
--- a/Modules/DiffusionImaging/FiberTracking/IODataStructures/FiberBundleX/mitkFiberBundleX.cpp
+++ b/Modules/DiffusionImaging/FiberTracking/IODataStructures/FiberBundleX/mitkFiberBundleX.cpp
@@ -1,1965 +1,2087 @@
 /*===================================================================
 
 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()
 {
     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) {
         MITK_DEBUG << "\n ========= Number of Fibers is 0 and below ========= \n";
         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);
 
         //    MITK_DEBUG << "Fib#: " << fi << " of " << numOfFibers << " pnts in fiber: " << pointsPerFiber ;
 
         /* 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;
             //      colorsT->InsertTupleValue(0, rgba);
 
         } else {
             MITK_DEBUG << "Fiber with 0 points detected... please check your tractography algorithm!" ;
             continue;
 
         }
 
 
     }//end for loop
 
     m_FiberPolyData->GetPointData()->AddArray(colorsT);
 
     /*=========================
       - this is more relevant for renderer than for fiberbundleX datastructure
       - think about sourcing this to a explicit method which coordinates colorcoding */
     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);
     MITK_DEBUG << "FBX: done CC 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);
     MITK_DEBUG << "FBX: done CC OPACITY";
     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)
 {
     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->ResampleFibers(minSpacing/10);
         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)
             {
                 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
             {
                 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->ResampleFibers(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->ResampleFibers(minSpacing/2);
     return newFib;
 }
 
 mitk::FiberBundleX::Pointer mitk::FiberBundleX::ExtractFiberSubset(mitk::PlanarFigure* pf)
 {
     if (pf==NULL)
         return NULL;
 
     std::vector<long> tmp = ExtractFiberIdSubset(pf);
 
     if (tmp.size()<=0)
         return mitk::FiberBundleX::New();
     vtkSmartPointer<vtkPolyData> pTmp = GeneratePolyDataByIds(tmp);
     return mitk::FiberBundleX::New(pTmp);
 }
 
 std::vector<long> mitk::FiberBundleX::ExtractFiberIdSubset(mitk::PlanarFigure* pf)
 {
     MITK_DEBUG << "Extracting fibers!";
     // vector which is returned, contains all extracted FiberIds
     std::vector<long> FibersInROI;
 
     if (pf==NULL)
         return FibersInROI;
 
     /* Handle type of planarfigure */
     // if incoming pf is a pfc
     mitk::PlanarFigureComposite::Pointer pfcomp= dynamic_cast<mitk::PlanarFigureComposite*>(pf);
     if (!pfcomp.IsNull()) {
         // process requested boolean operation of PFC
         switch (pfcomp->getOperationType()) {
         case 0:
         {
             MITK_DEBUG << "AND PROCESSING";
             //AND
             //temporarly store results of the child in this vector, we need that to accumulate the
             std::vector<long> childResults = this->ExtractFiberIdSubset(pfcomp->getChildAt(0));
             MITK_DEBUG << "first roi got fibers in ROI: " << childResults.size();
             MITK_DEBUG << "sorting...";
             std::sort(childResults.begin(), childResults.end());
             MITK_DEBUG << "sorting done";
             std::vector<long> AND_Assamblage(childResults.size());
             //std::vector<unsigned long> AND_Assamblage;
             fill(AND_Assamblage.begin(), AND_Assamblage.end(), -1);
             //AND_Assamblage.reserve(childResults.size()); //max size AND can reach anyway
 
             std::vector<long>::iterator it;
             for (int i=1; i<pfcomp->getNumberOfChildren(); ++i)
             {
                 std::vector<long> tmpChild = this->ExtractFiberIdSubset(pfcomp->getChildAt(i));
                 MITK_DEBUG << "ROI " << i << " has fibers in ROI: " << tmpChild.size();
                 sort(tmpChild.begin(), tmpChild.end());
 
                 it = std::set_intersection(childResults.begin(), childResults.end(),
                                            tmpChild.begin(), tmpChild.end(),
                                            AND_Assamblage.begin() );
             }
 
             MITK_DEBUG << "resize Vector";
             unsigned long i=0;
             while (i < AND_Assamblage.size() && AND_Assamblage[i] != -1){ //-1 represents a placeholder in the array
                 ++i;
             }
             AND_Assamblage.resize(i);
 
             MITK_DEBUG << "returning AND vector, size: " << AND_Assamblage.size();
             return AND_Assamblage;
             //            break;
 
         }
         case 1:
         {
             //OR
             std::vector<long> OR_Assamblage = this->ExtractFiberIdSubset(pfcomp->getChildAt(0));
             std::vector<long>::iterator it;
             MITK_DEBUG << OR_Assamblage.size();
 
             for (int i=1; i<pfcomp->getNumberOfChildren(); ++i) {
                 it = OR_Assamblage.end();
                 std::vector<long> tmpChild = this->ExtractFiberIdSubset(pfcomp->getChildAt(i));
                 OR_Assamblage.insert(it, tmpChild.begin(), tmpChild.end());
                 MITK_DEBUG << "ROI " << i << " has fibers in ROI: " << tmpChild.size() << " OR Assamblage: " << OR_Assamblage.size();
             }
 
             sort(OR_Assamblage.begin(), OR_Assamblage.end());
             it = unique(OR_Assamblage.begin(), OR_Assamblage.end());
             OR_Assamblage.resize( it - OR_Assamblage.begin() );
             MITK_DEBUG << "returning OR vector, size: " << OR_Assamblage.size();
 
             return OR_Assamblage;
         }
         case 2:
         {
             //NOT
             //get IDs of all fibers
             std::vector<long> childResults;
             childResults.reserve(this->GetNumFibers());
             vtkSmartPointer<vtkDataArray> idSet = m_FiberIdDataSet->GetCellData()->GetArray(FIBER_ID_ARRAY);
             MITK_DEBUG << "m_NumOfFib: " << this->GetNumFibers() << " cellIdNum: " << idSet->GetNumberOfTuples();
             for(long i=0; i<this->GetNumFibers(); i++)
             {
                 MITK_DEBUG << "i: " << i << " idset: " << idSet->GetTuple(i)[0];
                 childResults.push_back(idSet->GetTuple(i)[0]);
             }
 
             std::sort(childResults.begin(), childResults.end());
             std::vector<long> NOT_Assamblage(childResults.size());
             //fill it with -1, otherwise 0 will be stored and 0 can also be an ID of fiber!
             fill(NOT_Assamblage.begin(), NOT_Assamblage.end(), -1);
             std::vector<long>::iterator it;
 
             for (long i=0; i<pfcomp->getNumberOfChildren(); ++i)
             {
                 std::vector<long> tmpChild = ExtractFiberIdSubset(pfcomp->getChildAt(i));
                 sort(tmpChild.begin(), tmpChild.end());
 
                 it = std::set_difference(childResults.begin(), childResults.end(),
                                          tmpChild.begin(), tmpChild.end(),
                                          NOT_Assamblage.begin() );
 
             }
 
             MITK_DEBUG << "resize Vector";
             long i=0;
             while (NOT_Assamblage[i] != -1){ //-1 represents a placeholder in the array
                 ++i;
             }
             NOT_Assamblage.resize(i);
 
             return NOT_Assamblage;
         }
         default:
             MITK_DEBUG << "we have an UNDEFINED composition... ERROR" ;
             break;
 
         }
     }
     else
     {
-      mitk::PlaneGeometry::ConstPointer pfgeometry = pf->GetPlaneGeometry();
+        mitk::PlaneGeometry::ConstPointer pfgeometry = pf->GetPlaneGeometry();
         const mitk::PlaneGeometry* planeGeometry = dynamic_cast<const mitk::PlaneGeometry*> (pfgeometry.GetPointer());
         Vector3D planeNormal = planeGeometry->GetNormal();
         planeNormal.Normalize();
         Point3D planeOrigin = planeGeometry->GetOrigin();
 
         MITK_DEBUG << "planeOrigin: " << planeOrigin[0] << " | " << planeOrigin[1] << " | " << planeOrigin[2] << endl;
         MITK_DEBUG << "planeNormal: " << planeNormal[0] << " | " << planeNormal[1] << " | " << planeNormal[2] << endl;
 
         std::vector<int> PointsOnPlane; // contains all pointIds which are crossing the cutting plane
         std::vector<int> PointsInROI; // based on PointsOnPlane, all ROI relevant point IDs are stored here
 
         /* Define cutting plane by ROI (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 points/fibers cutting the plane */
         MITK_DEBUG << "start clipping";
         vtkSmartPointer<vtkClipPolyData> clipper = vtkSmartPointer<vtkClipPolyData>::New();
         clipper->SetInputData(m_FiberIdDataSet);
         clipper->SetClipFunction(plane);
         clipper->GenerateClipScalarsOn();
         clipper->GenerateClippedOutputOn();
         clipper->Update();
         vtkSmartPointer<vtkPolyData> clipperout = clipper->GetClippedOutput();
         MITK_DEBUG << "end clipping";
 
         MITK_DEBUG << "init and update clipperoutput";
-//        clipperout->GetPointData()->Initialize();
-//        clipperout->Update(); //VTK6_TODO
+        //        clipperout->GetPointData()->Initialize();
+        //        clipperout->Update(); //VTK6_TODO
         MITK_DEBUG << "init and update clipperoutput completed";
 
         MITK_DEBUG << "STEP 1: find all points which have distance 0 to the given plane";
         /*======STEP 1======
       * extract all points, which are crossing the plane */
         // Scalar values describe the distance between each remaining point to the given plane. Values sorted by point index
         vtkSmartPointer<vtkDataArray> distanceList = clipperout->GetPointData()->GetScalars();
         vtkIdType sizeOfList =  distanceList->GetNumberOfTuples();
         PointsOnPlane.reserve(sizeOfList); /* use reserve for high-performant push_back, no hidden copy procedures are processed then!
                                          * size of list can be optimized by reducing allocation, but be aware of iterator and vector size*/
 
         for (int i=0; i<sizeOfList; ++i) {
             double *distance = distanceList->GetTuple(i);
 
             // check if point is on plane.
             // 0.01 due to some approximation errors when calculating distance
             if (distance[0] >= -0.01 && distance[0] <= 0.01)
                 PointsOnPlane.push_back(i);
         }
 
 
         MITK_DEBUG << "Num Of points on plane: " <<  PointsOnPlane.size();
 
         MITK_DEBUG << "Step 2: extract Interesting points with respect to given extraction planarFigure";
 
         PointsInROI.reserve(PointsOnPlane.size());
         /*=======STEP 2=====
      * extract ROI relevant pointIds */
 
         mitk::PlanarCircle::Pointer circleName = mitk::PlanarCircle::New();
         mitk::PlanarPolygon::Pointer polyName = mitk::PlanarPolygon::New();
         if ( pf->GetNameOfClass() == circleName->GetNameOfClass() )
         {
             //calculate circle radius
             mitk::Point3D V1w = pf->GetWorldControlPoint(0); //centerPoint
             mitk::Point3D V2w  = pf->GetWorldControlPoint(1); //radiusPoint
 
             double distPF = V1w.EuclideanDistanceTo(V2w);
 
             for (unsigned int i=0; i<PointsOnPlane.size(); i++)
             {
                 //distance between circle radius and given point
                 double XdistPnt =  sqrt((double) (clipperout->GetPoint(PointsOnPlane[i])[0] - V1w[0]) * (clipperout->GetPoint(PointsOnPlane[i])[0] - V1w[0]) +
                         (clipperout->GetPoint(PointsOnPlane[i])[1] - V1w[1]) * (clipperout->GetPoint(PointsOnPlane[i])[1] - V1w[1]) +
                         (clipperout->GetPoint(PointsOnPlane[i])[2] - V1w[2]) * (clipperout->GetPoint(PointsOnPlane[i])[2] - V1w[2])) ;
 
                 if( XdistPnt <= distPF)
                     PointsInROI.push_back(PointsOnPlane[i]);
             }
         }
         else if ( pf->GetNameOfClass() == polyName->GetNameOfClass() )
         {
             //create vtkPolygon using controlpoints from planarFigure polygon
             vtkSmartPointer<vtkPolygon> polygonVtk = vtkSmartPointer<vtkPolygon>::New();
 
             //get the control points from pf and insert them to vtkPolygon
             unsigned int nrCtrlPnts = pf->GetNumberOfControlPoints();
 
             for (unsigned int i=0; i<nrCtrlPnts; ++i)
             {
                 polygonVtk->GetPoints()->InsertNextPoint((double)pf->GetWorldControlPoint(i)[0], (double)pf->GetWorldControlPoint(i)[1], (double)pf->GetWorldControlPoint(i)[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 checkIn[3] = {clipperout->GetPoint(PointsOnPlane[i])[0], clipperout->GetPoint(PointsOnPlane[i])[1], clipperout->GetPoint(PointsOnPlane[i])[2]};
                 int isInPolygon = polygonVtk->PointInPolygon(checkIn, polygonVtk->GetPoints()->GetNumberOfPoints()
                                                              , static_cast<double*>(polygonVtk->GetPoints()->GetData()->GetVoidPointer(0)), bounds, n);
                 if( isInPolygon )
                     PointsInROI.push_back(PointsOnPlane[i]);
             }
         }
 
         MITK_DEBUG << "Step3: Identify fibers";
         // we need to access the fiberId Array, so make sure that this array is available
         if (!clipperout->GetCellData()->HasArray(FIBER_ID_ARRAY))
         {
             MITK_DEBUG << "ERROR: FiberID array does not exist, no correlation between points and fiberIds possible! Make sure calling GenerateFiberIds()";
             return FibersInROI; // FibersInRoi is empty then
         }
         if (PointsInROI.size()<=0)
             return FibersInROI;
 
         // prepare a structure where each point id is represented as an indexId.
         // vector looks like: | pntId | fiberIdx |
         std::vector< long > pointindexFiberMap;
 
         // walk through the whole subline section and create an vector sorted by point index
         vtkCellArray *clipperlines = clipperout->GetLines();
         clipperlines->InitTraversal();
         long numOfLineCells = clipperlines->GetNumberOfCells();
         long numofClippedPoints = clipperout->GetNumberOfPoints();
         pointindexFiberMap.resize(numofClippedPoints);
 
 
         //prepare resulting vector
         FibersInROI.reserve(PointsInROI.size());
 
         MITK_DEBUG << "\n===== Pointindex based structure initialized ======\n";
 
         // go through resulting "sub"lines which are stored as cells, "i" corresponds to current line id.
         for (int i=0, ic=0 ; i<numOfLineCells; i++, ic+=3)
         { //ic is the index counter for the cells hosting the desired information, eg. 2 | 45 | 46. each cell consits of 3 items.
 
             vtkIdType npts;
             vtkIdType *pts;
             clipperlines->GetCell(ic, npts, pts);
 
             // go through point ids in hosting subline, "j" corresponds to current pointindex in current line i. eg. idx[0]=45; idx[1]=46
             for (long j=0; j<npts; j++)
             {
                 // MITK_DEBUG << "writing fiber id: " << clipperout->GetCellData()->GetArray(FIBER_ID_ARRAY)->GetTuple(i)[0] << " to pointId: " << pts[j];
                 pointindexFiberMap[ pts[j] ] = clipperout->GetCellData()->GetArray(FIBER_ID_ARRAY)->GetTuple(i)[0];
                 // MITK_DEBUG << "in array: " << pointindexFiberMap[ pts[j] ];
             }
 
         }
 
         MITK_DEBUG << "\n===== Pointindex based structure finalized ======\n";
 
         // get all Points in ROI with according fiberID
         for (unsigned long k = 0; k < PointsInROI.size(); k++)
         {
             //MITK_DEBUG << "point " << PointsInROI[k] << " belongs to fiber " << pointindexFiberMap[ PointsInROI[k] ];
             if (pointindexFiberMap[ PointsInROI[k] ]<=GetNumFibers() && pointindexFiberMap[ PointsInROI[k] ]>=0)
                 FibersInROI.push_back(pointindexFiberMap[ PointsInROI[k] ]);
             else
                 MITK_INFO << "ERROR in ExtractFiberIdSubset; impossible fiber id detected";
         }
 
         m_PointsRoi = PointsInROI;
 
     }
 
     //  detecting fiberId duplicates
     MITK_DEBUG << "check for duplicates";
 
     sort(FibersInROI.begin(), FibersInROI.end());
     bool hasDuplicats = false;
     for(unsigned long i=0; i<FibersInROI.size()-1; ++i)
     {
         if(FibersInROI[i] == FibersInROI[i+1])
             hasDuplicats = true;
     }
 
     if(hasDuplicats)
     {
         std::vector<long>::iterator it;
         it = unique (FibersInROI.begin(), FibersInROI.end());
         FibersInROI.resize( it - FibersInROI.begin() );
     }
 
     return FibersInROI;
 }
 
 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(true);
         float b[] = {0, 1, 0, 1, 0, 1};
         geometry->SetFloatBounds(b);
         SetGeometry(geometry);
         return;
     }
     float min = itk::NumericTraits<float>::NonpositiveMin();
     float max = itk::NumericTraits<float>::max();
     float b[] = {max, min, max, min, max, min};
 
     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; j++)
         {
             // calculate bounding box
             double p1[3];
             points->GetPoint(j, p1);
 
             if (p1[0]<b[0])
                 b[0]=p1[0];
             if (p1[0]>b[1])
                 b[1]=p1[0];
 
             if (p1[1]<b[2])
                 b[2]=p1[1];
             if (p1[1]>b[3])
                 b[3]=p1[1];
 
             if (p1[2]<b[4])
                 b[4]=p1[2];
             if (p1[2]>b[5])
                 b[5]=p1[2];
 
             // calculate statistics
             if (j<p-1)
             {
                 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);
 
     // provide some border margin
     for(int i=0; i<=4; i+=2)
         b[i] -=10;
     for(int i=1; i<=5; i+=2)
         b[i] +=10;
 
     mitk::Geometry3D::Pointer geometry = mitk::Geometry3D::New();
     geometry->SetFloatBounds(b);
     this->SetGeometry(geometry);
 }
 
 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;
     MITK_DEBUG << "SetColorCoding:" << requestedColorCoding;
 
     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
     }
 }
 
 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)
 {
     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);
             p[0] -= c[0]; p[1] -= c[1]; p[2] -= c[2];
             p[0] *= x;
             p[1] *= y;
             p[2] *= z;
             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::DoFiberSmoothing(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::DoFiberSmoothing(float pointDistance)
 {
     DoFiberSmoothing(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::CompressFibers(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::ResampleFibers(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 fee2bf35b1..267054291f 100644
--- a/Modules/DiffusionImaging/FiberTracking/IODataStructures/FiberBundleX/mitkFiberBundleX.h
+++ b/Modules/DiffusionImaging/FiberTracking/IODataStructures/FiberBundleX/mitkFiberBundleX.h
@@ -1,170 +1,172 @@
 /*===================================================================
 
 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>
 
 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 smoothing/resampling
+    void CompressFibers(float error = 0.0);
     void ResampleFibers(float pointDistance = 1);
     void DoFiberSmoothing(float pointDistance);
     void DoFiberSmoothing(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);
     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(PlanarFigure *pf);
     std::vector<long>               ExtractFiberIdSubset(PlanarFigure* pf);
     FiberBundleX::Pointer           ExtractFiberSubset(ItkUcharImgType* mask, bool anyPoint);
     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();
     std::vector< std::string > GetAvailableColorCodings();
     char* GetCurrentColorCoding();
     itkGetMacro( NumFibers, int)
     itkGetMacro( FiberSampling, int)
     itkGetMacro( MinFiberLength, float )
     itkGetMacro( MaxFiberLength, float )
     itkGetMacro( MeanFiberLength, float )
     itkGetMacro( MedianFiberLength, float )
     itkGetMacro( LengthStDev, float )
+    unsigned long GetNumberOfPoints();
 
     std::vector<int> GetPointsRoi()
     {
         return m_PointsRoi;
     }
 
     // copy fiber bundle
     mitk::FiberBundleX::Pointer GetDeepCopy();
 
     // compare fiber bundles
     bool Equals(FiberBundleX* fib, double eps=0.0001);
 
     itkSetMacro( ReferenceImage, mitk::Image::Pointer )
     itkGetMacro( ReferenceImage, mitk::Image::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;
 
     std::vector<int> m_PointsRoi; // this global variable needs to be refactored
 
     mitk::Image::Pointer m_ReferenceImage;
 
 };
 
 } // namespace mitk
 
 #endif /*  _MITK_FiberBundleX_H */
diff --git a/Plugins/org.mitk.gui.qt.diffusionimaging/src/internal/QmitkFiberProcessingView.cpp b/Plugins/org.mitk.gui.qt.diffusionimaging/src/internal/QmitkFiberProcessingView.cpp
index fae4bfdc7e..05823a7544 100644
--- a/Plugins/org.mitk.gui.qt.diffusionimaging/src/internal/QmitkFiberProcessingView.cpp
+++ b/Plugins/org.mitk.gui.qt.diffusionimaging/src/internal/QmitkFiberProcessingView.cpp
@@ -1,470 +1,486 @@
 /*===================================================================
 
 The Medical Imaging Interaction Toolkit (MITK)
 
 Copyright (c) German Cancer Research Center,
 Division of Medical and Biological Informatics.
 All rights reserved.
 
 This software is distributed WITHOUT ANY WARRANTY; without
 even the implied warranty of MERCHANTABILITY or FITNESS FOR
 A PARTICULAR PURPOSE.
 
 See LICENSE.txt or http://www.mitk.org for details.
 
 ===================================================================*/
 
 
 // Blueberry
 #include <berryISelectionService.h>
 #include <berryIWorkbenchWindow.h>
 
 // Qmitk
 #include "QmitkFiberProcessingView.h"
 #include <QmitkStdMultiWidget.h>
 
 // Qt
 #include <QMessageBox>
 
 // MITK
 #include <mitkNodePredicateProperty.h>
 #include <mitkImageCast.h>
 #include <mitkPointSet.h>
 #include <mitkPlanarCircle.h>
 #include <mitkPlanarPolygon.h>
 #include <mitkPlanarRectangle.h>
 #include <mitkPlanarFigureInteractor.h>
 #include <mitkGlobalInteraction.h>
 #include <mitkImageAccessByItk.h>
 #include <mitkDataNodeObject.h>
 #include <mitkDiffusionImage.h>
 #include <mitkTensorImage.h>
 
 // ITK
 #include <itkResampleImageFilter.h>
 #include <itkGaussianInterpolateImageFunction.h>
 #include <itkImageRegionIteratorWithIndex.h>
 #include <itkTractsToFiberEndingsImageFilter.h>
 #include <itkTractDensityImageFilter.h>
 #include <itkImageRegion.h>
 #include <itkTractsToRgbaImageFilter.h>
 
 #include <math.h>
 
 
 const std::string QmitkFiberProcessingView::VIEW_ID = "org.mitk.views.fiberprocessing";
 const std::string id_DataManager = "org.mitk.views.datamanager";
 using namespace mitk;
 
 QmitkFiberProcessingView::QmitkFiberProcessingView()
     : QmitkFunctionality()
     , m_Controls( 0 )
     , m_MultiWidget( NULL )
     , m_UpsamplingFactor(5)
 {
 
 }
 
 // Destructor
 QmitkFiberProcessingView::~QmitkFiberProcessingView()
 {
 
 }
 
 void QmitkFiberProcessingView::CreateQtPartControl( QWidget *parent )
 {
     // build up qt view, unless already done
     if ( !m_Controls )
     {
         // create GUI widgets from the Qt Designer's .ui file
         m_Controls = new Ui::QmitkFiberProcessingViewControls;
         m_Controls->setupUi( parent );
 
         connect( m_Controls->m_ProcessFiberBundleButton, SIGNAL(clicked()), this, SLOT(ProcessSelectedBundles()) );
         connect( m_Controls->m_ResampleFibersButton, SIGNAL(clicked()), this, SLOT(ResampleSelectedBundles()) );
         connect(m_Controls->m_FaColorFibersButton, SIGNAL(clicked()), this, SLOT(DoImageColorCoding()));
         connect( m_Controls->m_PruneFibersButton, SIGNAL(clicked()), this, SLOT(PruneBundle()) );
         connect( m_Controls->m_CurvatureThresholdButton, SIGNAL(clicked()), this, SLOT(ApplyCurvatureThreshold()) );
         connect( m_Controls->m_MirrorFibersButton, SIGNAL(clicked()), this, SLOT(MirrorFibers()) );
+        connect( m_Controls->m_CompressFibersButton, SIGNAL(clicked()), this, SLOT(CompressSelectedBundles()) );
     }
 }
 
 void QmitkFiberProcessingView::StdMultiWidgetAvailable (QmitkStdMultiWidget &stdMultiWidget)
 {
     m_MultiWidget = &stdMultiWidget;
 }
 
 
 void QmitkFiberProcessingView::StdMultiWidgetNotAvailable()
 {
     m_MultiWidget = NULL;
 }
 
 void QmitkFiberProcessingView::UpdateGui()
 {
     // are fiber bundles selected?
     if ( m_SelectedFB.empty() )
     {
+        m_Controls->m_CompressFibersButton->setEnabled(false);
         m_Controls->m_ProcessFiberBundleButton->setEnabled(false);
         m_Controls->m_ResampleFibersButton->setEnabled(false);
         m_Controls->m_FaColorFibersButton->setEnabled(false);
         m_Controls->m_PruneFibersButton->setEnabled(false);
         m_Controls->m_CurvatureThresholdButton->setEnabled(false);
 
         if (m_SelectedSurfaces.size()>0)
             m_Controls->m_MirrorFibersButton->setEnabled(true);
         else
             m_Controls->m_MirrorFibersButton->setEnabled(false);
     }
     else
     {
+        m_Controls->m_CompressFibersButton->setEnabled(true);
         m_Controls->m_ProcessFiberBundleButton->setEnabled(true);
         m_Controls->m_ResampleFibersButton->setEnabled(true);
         m_Controls->m_PruneFibersButton->setEnabled(true);
         m_Controls->m_CurvatureThresholdButton->setEnabled(true);
         m_Controls->m_MirrorFibersButton->setEnabled(true);
 
         if (m_SelectedImage.IsNotNull())
             m_Controls->m_FaColorFibersButton->setEnabled(true);
     }
 }
 
 void QmitkFiberProcessingView::OnSelectionChanged( std::vector<mitk::DataNode*> nodes )
 {
     //reset existing Vectors containing FiberBundles and PlanarFigures from a previous selection
     m_SelectedFB.clear();
     m_SelectedSurfaces.clear();
     m_SelectedImage = NULL;
 
     for( std::vector<mitk::DataNode*>::iterator it = nodes.begin(); it != nodes.end(); ++it )
     {
         mitk::DataNode::Pointer node = *it;
         if ( dynamic_cast<mitk::FiberBundleX*>(node->GetData()) )
         {
             m_SelectedFB.push_back(node);
         }
         else if (dynamic_cast<mitk::Image*>(node->GetData()))
             m_SelectedImage = dynamic_cast<mitk::Image*>(node->GetData());
         else if (dynamic_cast<mitk::Surface*>(node->GetData()))
         {
             m_SelectedSurfaces.push_back(dynamic_cast<mitk::Surface*>(node->GetData()));
         }
     }
     UpdateGui();
     GenerateStats();
 }
 
 void QmitkFiberProcessingView::Activated()
 {
 
 }
 
 void QmitkFiberProcessingView::PruneBundle()
 {
     int minLength = this->m_Controls->m_PruneFibersSpinBox->value();
     int maxLength = this->m_Controls->m_MaxPruneFibersSpinBox->value();
     for (int i=0; i<m_SelectedFB.size(); i++)
     {
         mitk::FiberBundleX::Pointer fib = dynamic_cast<mitk::FiberBundleX*>(m_SelectedFB.at(i)->GetData());
         if (!fib->RemoveShortFibers(minLength))
             QMessageBox::information(NULL, "No output generated:", "The resulting fiber bundle contains no fibers.");
         else if (!fib->RemoveLongFibers(maxLength))
             QMessageBox::information(NULL, "No output generated:", "The resulting fiber bundle contains no fibers.");
     }
     GenerateStats();
     RenderingManager::GetInstance()->RequestUpdateAll();
 }
 
 
 void QmitkFiberProcessingView::ApplyCurvatureThreshold()
 {
     int mm = this->m_Controls->m_MinCurvatureRadiusBox->value();
     for (int i=0; i<m_SelectedFB.size(); i++)
     {
         mitk::FiberBundleX::Pointer fib = dynamic_cast<mitk::FiberBundleX*>(m_SelectedFB.at(i)->GetData());
         if (!fib->ApplyCurvatureThreshold(mm, this->m_Controls->m_RemoveFiberDueToCurvatureCheckbox->isChecked()))
             QMessageBox::information(NULL, "No output generated:", "The resulting fiber bundle contains no fibers.");
     }
     GenerateStats();
     RenderingManager::GetInstance()->RequestUpdateAll();
 }
 
 void QmitkFiberProcessingView::GenerateStats()
 {
     if ( m_SelectedFB.empty() )
         return;
 
     QString stats("");
 
     for( int i=0; i<m_SelectedFB.size(); i++ )
     {
         mitk::DataNode::Pointer node = m_SelectedFB[i];
         if (node.IsNotNull() && dynamic_cast<mitk::FiberBundleX*>(node->GetData()))
         {
             if (i>0)
                 stats += "\n-----------------------------\n";
             stats += QString(node->GetName().c_str()) + "\n";
             mitk::FiberBundleX::Pointer fib = dynamic_cast<mitk::FiberBundleX*>(node->GetData());
             stats += "Number of fibers: "+ QString::number(fib->GetNumFibers()) + "\n";
+            stats += "Number of points: "+ QString::number(fib->GetNumberOfPoints()) + "\n";
             stats += "Min. length:         "+ QString::number(fib->GetMinFiberLength(),'f',1) + " mm\n";
             stats += "Max. length:         "+ QString::number(fib->GetMaxFiberLength(),'f',1) + " mm\n";
             stats += "Mean length:         "+ QString::number(fib->GetMeanFiberLength(),'f',1) + " mm\n";
             stats += "Median length:       "+ QString::number(fib->GetMedianFiberLength(),'f',1) + " mm\n";
             stats += "Standard deviation:  "+ QString::number(fib->GetLengthStDev(),'f',1) + " mm\n";
         }
     }
     this->m_Controls->m_StatsTextEdit->setText(stats);
 }
 
 void QmitkFiberProcessingView::ProcessSelectedBundles()
 {
     if ( m_SelectedFB.empty() ){
         QMessageBox::information( NULL, "Warning", "No fibe bundle selected!");
         MITK_WARN("QmitkFiberProcessingView") << "no fibe bundle selected";
         return;
     }
 
     int generationMethod = m_Controls->m_GenerationBox->currentIndex();
 
     for( int i=0; i<m_SelectedFB.size(); i++ )
     {
         mitk::DataNode::Pointer node = m_SelectedFB[i];
         if (node.IsNotNull() && dynamic_cast<mitk::FiberBundleX*>(node->GetData()))
         {
             mitk::FiberBundleX::Pointer fib = dynamic_cast<mitk::FiberBundleX*>(node->GetData());
             QString name(node->GetName().c_str());
             DataNode::Pointer newNode = NULL;
             switch(generationMethod){
             case 0:
                 newNode = GenerateTractDensityImage(fib, false, true);
                 name += "_TDI";
                 break;
             case 1:
                 newNode = GenerateTractDensityImage(fib, false, false);
                 name += "_TDI";
                 break;
             case 2:
                 newNode = GenerateTractDensityImage(fib, true, false);
                 name += "_envelope";
                 break;
             case 3:
                 newNode = GenerateColorHeatmap(fib);
                 break;
             case 4:
                 newNode = GenerateFiberEndingsImage(fib);
                 name += "_fiber_endings";
                 break;
             case 5:
                 newNode = GenerateFiberEndingsPointSet(fib);
                 name += "_fiber_endings";
                 break;
             }
             if (newNode.IsNotNull())
             {
                 newNode->SetName(name.toStdString());
                 GetDataStorage()->Add(newNode);
             }
         }
     }
 }
 
 // generate pointset displaying the fiber endings
 mitk::DataNode::Pointer QmitkFiberProcessingView::GenerateFiberEndingsPointSet(mitk::FiberBundleX::Pointer fib)
 {
     mitk::PointSet::Pointer pointSet = mitk::PointSet::New();
     vtkSmartPointer<vtkPolyData> fiberPolyData = fib->GetFiberPolyData();
     vtkSmartPointer<vtkCellArray> vLines = fiberPolyData->GetLines();
     vLines->InitTraversal();
 
     int count = 0;
     int numFibers = fib->GetNumFibers();
     for( int i=0; i<numFibers; i++ )
     {
         vtkIdType   numPoints(0);
         vtkIdType*  points(NULL);
         vLines->GetNextCell ( numPoints, points );
 
         if (numPoints>0)
         {
             double* point = fiberPolyData->GetPoint(points[0]);
             itk::Point<float,3> itkPoint;
             itkPoint[0] = point[0];
             itkPoint[1] = point[1];
             itkPoint[2] = point[2];
             pointSet->InsertPoint(count, itkPoint);
             count++;
         }
         if (numPoints>2)
         {
             double* point = fiberPolyData->GetPoint(points[numPoints-1]);
             itk::Point<float,3> itkPoint;
             itkPoint[0] = point[0];
             itkPoint[1] = point[1];
             itkPoint[2] = point[2];
             pointSet->InsertPoint(count, itkPoint);
             count++;
         }
     }
 
     mitk::DataNode::Pointer node = mitk::DataNode::New();
     node->SetData( pointSet );
     return node;
 }
 
 // generate image displaying the fiber endings
 mitk::DataNode::Pointer QmitkFiberProcessingView::GenerateFiberEndingsImage(mitk::FiberBundleX::Pointer fib)
 {
     typedef unsigned char OutPixType;
     typedef itk::Image<OutPixType,3> OutImageType;
 
     typedef itk::TractsToFiberEndingsImageFilter< OutImageType > ImageGeneratorType;
     ImageGeneratorType::Pointer generator = ImageGeneratorType::New();
     generator->SetFiberBundle(fib);
     generator->SetUpsamplingFactor(m_Controls->m_UpsamplingSpinBox->value());
     if (m_SelectedImage.IsNotNull())
     {
         OutImageType::Pointer itkImage = OutImageType::New();
         CastToItkImage(m_SelectedImage, itkImage);
         generator->SetInputImage(itkImage);
         generator->SetUseImageGeometry(true);
     }
     generator->Update();
 
     // get output image
     OutImageType::Pointer outImg = generator->GetOutput();
     mitk::Image::Pointer img = mitk::Image::New();
     img->InitializeByItk(outImg.GetPointer());
     img->SetVolume(outImg->GetBufferPointer());
 
     // init data node
     mitk::DataNode::Pointer node = mitk::DataNode::New();
     node->SetData(img);
     return node;
 }
 
 // generate rgba heatmap from fiber bundle
 mitk::DataNode::Pointer QmitkFiberProcessingView::GenerateColorHeatmap(mitk::FiberBundleX::Pointer fib)
 {
     typedef itk::RGBAPixel<unsigned char> OutPixType;
     typedef itk::Image<OutPixType, 3> OutImageType;
     typedef itk::TractsToRgbaImageFilter< OutImageType > ImageGeneratorType;
     ImageGeneratorType::Pointer generator = ImageGeneratorType::New();
     generator->SetFiberBundle(fib);
     generator->SetUpsamplingFactor(m_Controls->m_UpsamplingSpinBox->value());
     if (m_SelectedImage.IsNotNull())
     {
         itk::Image<unsigned char, 3>::Pointer itkImage = itk::Image<unsigned char, 3>::New();
         CastToItkImage(m_SelectedImage, itkImage);
         generator->SetInputImage(itkImage);
         generator->SetUseImageGeometry(true);
     }
     generator->Update();
 
     // get output image
     typedef itk::Image<OutPixType,3> OutType;
     OutType::Pointer outImg = generator->GetOutput();
     mitk::Image::Pointer img = mitk::Image::New();
     img->InitializeByItk(outImg.GetPointer());
     img->SetVolume(outImg->GetBufferPointer());
 
     // init data node
     mitk::DataNode::Pointer node = mitk::DataNode::New();
     node->SetData(img);
     return node;
 }
 
 // generate tract density image from fiber bundle
 mitk::DataNode::Pointer QmitkFiberProcessingView::GenerateTractDensityImage(mitk::FiberBundleX::Pointer fib, bool binary, bool absolute)
 {
     typedef float OutPixType;
     typedef itk::Image<OutPixType, 3> OutImageType;
 
     itk::TractDensityImageFilter< OutImageType >::Pointer generator = itk::TractDensityImageFilter< OutImageType >::New();
     generator->SetFiberBundle(fib);
     generator->SetBinaryOutput(binary);
     generator->SetOutputAbsoluteValues(absolute);
     generator->SetUpsamplingFactor(m_Controls->m_UpsamplingSpinBox->value());
     if (m_SelectedImage.IsNotNull())
     {
         OutImageType::Pointer itkImage = OutImageType::New();
         CastToItkImage(m_SelectedImage, itkImage);
         generator->SetInputImage(itkImage);
         generator->SetUseImageGeometry(true);
 
     }
     generator->Update();
 
     // get output image
     typedef itk::Image<OutPixType,3> OutType;
     OutType::Pointer outImg = generator->GetOutput();
     mitk::Image::Pointer img = mitk::Image::New();
     img->InitializeByItk(outImg.GetPointer());
     img->SetVolume(outImg->GetBufferPointer());
 
     // init data node
     mitk::DataNode::Pointer node = mitk::DataNode::New();
     node->SetData(img);
     return node;
 }
 
 void QmitkFiberProcessingView::ResampleSelectedBundles()
 {
     double factor = this->m_Controls->m_ResampleFibersSpinBox->value();
     for (int i=0; i<m_SelectedFB.size(); i++)
     {
         mitk::FiberBundleX::Pointer fib = dynamic_cast<mitk::FiberBundleX*>(m_SelectedFB.at(i)->GetData());
         fib->DoFiberSmoothing(factor);
     }
     GenerateStats();
     RenderingManager::GetInstance()->RequestUpdateAll();
 }
 
+void QmitkFiberProcessingView::CompressSelectedBundles()
+{
+    double factor = this->m_Controls->m_FiberErrorSpinBox->value();
+    for (int i=0; i<m_SelectedFB.size(); i++)
+    {
+        mitk::FiberBundleX::Pointer fib = dynamic_cast<mitk::FiberBundleX*>(m_SelectedFB.at(i)->GetData());
+        fib->CompressFibers(factor);
+    }
+    GenerateStats();
+    RenderingManager::GetInstance()->RequestUpdateAll();
+}
+
 void QmitkFiberProcessingView::MirrorFibers()
 {
     unsigned int axis = this->m_Controls->m_AxisSelectionBox->currentIndex();
     for (int i=0; i<m_SelectedFB.size(); i++)
     {
         mitk::FiberBundleX::Pointer fib = dynamic_cast<mitk::FiberBundleX*>(m_SelectedFB.at(i)->GetData());
         fib->MirrorFibers(axis);
     }
     if (m_SelectedFB.size()>0)
         GenerateStats();
 
     if (m_SelectedSurfaces.size()>0)
     {
         for (int i=0; i<m_SelectedSurfaces.size(); i++)
         {
             mitk::Surface::Pointer surf = m_SelectedSurfaces.at(i);
             vtkSmartPointer<vtkPolyData> poly = surf->GetVtkPolyData();
             vtkSmartPointer<vtkPoints> vtkNewPoints = vtkSmartPointer<vtkPoints>::New();
 
             for (int i=0; i<poly->GetNumberOfPoints(); i++)
             {
                 double* point = poly->GetPoint(i);
                 point[axis] *= -1;
                 vtkNewPoints->InsertNextPoint(point);
             }
             poly->SetPoints(vtkNewPoints);
             surf->CalculateBoundingBox();
         }
     }
 
     RenderingManager::GetInstance()->RequestUpdateAll();
 }
 
 void QmitkFiberProcessingView::DoImageColorCoding()
 {
     if (m_SelectedImage.IsNull())
         return;
 
     for( int i=0; i<m_SelectedFB.size(); i++ )
     {
         mitk::FiberBundleX::Pointer fib = dynamic_cast<mitk::FiberBundleX*>(m_SelectedFB.at(i)->GetData());
         fib->SetFAMap(m_SelectedImage);
         fib->SetColorCoding(mitk::FiberBundleX::COLORCODING_FA_BASED);
         fib->DoColorCodingFaBased();
     }
 
     if(m_MultiWidget)
         m_MultiWidget->RequestUpdate();
 }
diff --git a/Plugins/org.mitk.gui.qt.diffusionimaging/src/internal/QmitkFiberProcessingView.h b/Plugins/org.mitk.gui.qt.diffusionimaging/src/internal/QmitkFiberProcessingView.h
index cccc42e14a..11809cf546 100644
--- a/Plugins/org.mitk.gui.qt.diffusionimaging/src/internal/QmitkFiberProcessingView.h
+++ b/Plugins/org.mitk.gui.qt.diffusionimaging/src/internal/QmitkFiberProcessingView.h
@@ -1,154 +1,155 @@
 /*===================================================================
 
 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 QmitkFiberProcessingView_h
 #define QmitkFiberProcessingView_h
 
 #include <QmitkFunctionality.h>
 #include "ui_QmitkFiberProcessingViewControls.h"
 
 #include <mitkPlanarFigureComposite.h>
 #include <mitkFiberBundleX.h>
 #include <mitkSurface.h>
 
 #include <itkCastImageFilter.h>
 #include <itkVTKImageImport.h>
 #include <itkVTKImageExport.h>
 #include <itkRegionOfInterestImageFilter.h>
 
 #include <vtkLinearExtrusionFilter.h>
 #include <vtkPolyDataToImageStencil.h>
 #include <vtkSelectEnclosedPoints.h>
 #include <vtkImageImport.h>
 #include <vtkImageExport.h>
 #include <vtkImageStencil.h>
 #include <vtkSmartPointer.h>
 #include <vtkSelection.h>
 #include <vtkSelectionNode.h>
 #include <vtkExtractSelectedThresholds.h>
 #include <vtkFloatArray.h>
 
 /*!
 \brief View to process fiber bundles. Supplies methods to generate images from the selected bundle and much more.
 
 \sa QmitkFunctionality
 \ingroup Functionalities
 */
 class QmitkFiberProcessingView : public QmitkFunctionality
 {
   // this is needed for all Qt objects that should have a Qt meta-object
   // (everything that derives from QObject and wants to have signal/slots)
   Q_OBJECT
 
 public:
 
   typedef itk::Image< unsigned char, 3 >    itkUCharImageType;
 
   static const std::string VIEW_ID;
 
   QmitkFiberProcessingView();
   virtual ~QmitkFiberProcessingView();
 
   virtual void CreateQtPartControl(QWidget *parent);
 
   virtual void StdMultiWidgetAvailable (QmitkStdMultiWidget &stdMultiWidget);
   virtual void StdMultiWidgetNotAvailable();
   virtual void Activated();
 
 protected slots:
 
   void PruneBundle();               ///< remove too short/too long fibers
   void MirrorFibers();              ///< mirror bundle on the specified plane
   void ProcessSelectedBundles();    ///< start selected operation on fiber bundle (e.g. tract density image generation)
   void ResampleSelectedBundles();   ///< smooth fiber bundle using the specified number of sampling points per cm.
   void DoImageColorCoding();        ///< color fibers by selected scalar image
   void ApplyCurvatureThreshold();   ///< remove/split fibers with a too high curvature threshold
+  void CompressSelectedBundles();   ///< remove points below certain error threshold
 
 protected:
 
   /// \brief called by QmitkFunctionality when DataManager's selection has changed
   virtual void OnSelectionChanged( std::vector<mitk::DataNode*> nodes );
 
   Ui::QmitkFiberProcessingViewControls* m_Controls;
   QmitkStdMultiWidget* m_MultiWidget;
 
   /** Connection from VTK to ITK */
   template <typename VTK_Exporter, typename ITK_Importer>
       void ConnectPipelines(VTK_Exporter* exporter, ITK_Importer importer)
   {
     importer->SetUpdateInformationCallback(exporter->GetUpdateInformationCallback());
 
     importer->SetPipelineModifiedCallback(exporter->GetPipelineModifiedCallback());
     importer->SetWholeExtentCallback(exporter->GetWholeExtentCallback());
     importer->SetSpacingCallback(exporter->GetSpacingCallback());
     importer->SetOriginCallback(exporter->GetOriginCallback());
     importer->SetScalarTypeCallback(exporter->GetScalarTypeCallback());
 
     importer->SetNumberOfComponentsCallback(exporter->GetNumberOfComponentsCallback());
 
     importer->SetPropagateUpdateExtentCallback(exporter->GetPropagateUpdateExtentCallback());
     importer->SetUpdateDataCallback(exporter->GetUpdateDataCallback());
     importer->SetDataExtentCallback(exporter->GetDataExtentCallback());
     importer->SetBufferPointerCallback(exporter->GetBufferPointerCallback());
     importer->SetCallbackUserData(exporter->GetCallbackUserData());
   }
 
   template <typename ITK_Exporter, typename VTK_Importer>
       void ConnectPipelines(ITK_Exporter exporter, VTK_Importer* importer)
   {
     importer->SetUpdateInformationCallback(exporter->GetUpdateInformationCallback());
 
     importer->SetPipelineModifiedCallback(exporter->GetPipelineModifiedCallback());
     importer->SetWholeExtentCallback(exporter->GetWholeExtentCallback());
     importer->SetSpacingCallback(exporter->GetSpacingCallback());
     importer->SetOriginCallback(exporter->GetOriginCallback());
     importer->SetScalarTypeCallback(exporter->GetScalarTypeCallback());
 
     importer->SetNumberOfComponentsCallback(exporter->GetNumberOfComponentsCallback());
 
     importer->SetPropagateUpdateExtentCallback(exporter->GetPropagateUpdateExtentCallback());
     importer->SetUpdateDataCallback(exporter->GetUpdateDataCallback());
     importer->SetDataExtentCallback(exporter->GetDataExtentCallback());
     importer->SetBufferPointerCallback(exporter->GetBufferPointerCallback());
     importer->SetCallbackUserData(exporter->GetCallbackUserData());
   }
 
   template < typename TPixel, unsigned int VImageDimension >
       void InternalCalculateMaskFromPlanarFigure(
           itk::Image< TPixel, VImageDimension > *image, unsigned int axis, std::string nodeName );
 
   template < typename TPixel, unsigned int VImageDimension >
       void InternalReorientImagePlane(
           const itk::Image< TPixel, VImageDimension > *image, mitk::Geometry3D* planegeo3D, int additionalIndex );
 
   void GenerateStats(); ///< generate statistics of selected fiber bundles
   void UpdateGui();     ///< update button activity etc. dpending on current datamanager selection
 
   std::vector<mitk::DataNode::Pointer>  m_SelectedFB;       ///< selected fiber bundle nodes
   mitk::Image::Pointer                  m_SelectedImage;
   float                                 m_UpsamplingFactor; ///< upsampling factor for all image generations
   std::vector<mitk::Surface::Pointer>   m_SelectedSurfaces;
 
   mitk::DataNode::Pointer GenerateTractDensityImage(mitk::FiberBundleX::Pointer fib, bool binary, bool absolute);
   mitk::DataNode::Pointer GenerateColorHeatmap(mitk::FiberBundleX::Pointer fib);
   mitk::DataNode::Pointer GenerateFiberEndingsImage(mitk::FiberBundleX::Pointer fib);
   mitk::DataNode::Pointer GenerateFiberEndingsPointSet(mitk::FiberBundleX::Pointer fib);
 };
 
 
 
 #endif // _QMITKFIBERTRACKINGVIEW_H_INCLUDED
 
diff --git a/Plugins/org.mitk.gui.qt.diffusionimaging/src/internal/QmitkFiberProcessingViewControls.ui b/Plugins/org.mitk.gui.qt.diffusionimaging/src/internal/QmitkFiberProcessingViewControls.ui
index d5ef063f7d..167ce23d86 100644
--- a/Plugins/org.mitk.gui.qt.diffusionimaging/src/internal/QmitkFiberProcessingViewControls.ui
+++ b/Plugins/org.mitk.gui.qt.diffusionimaging/src/internal/QmitkFiberProcessingViewControls.ui
@@ -1,480 +1,559 @@
 <?xml version="1.0" encoding="UTF-8"?>
 <ui version="4.0">
  <class>QmitkFiberProcessingViewControls</class>
  <widget class="QWidget" name="QmitkFiberProcessingViewControls">
   <property name="geometry">
    <rect>
     <x>0</x>
     <y>0</y>
-    <width>492</width>
+    <width>498</width>
     <height>866</height>
    </rect>
   </property>
   <property name="windowTitle">
    <string>Form</string>
   </property>
   <layout class="QGridLayout" name="gridLayout_10">
    <item row="1" column="0">
     <widget class="QGroupBox" name="groupBox_3">
      <property name="title">
       <string>Fiber Statistics</string>
      </property>
      <layout class="QGridLayout" name="gridLayout_2">
       <item row="0" column="0">
        <widget class="QTextEdit" name="m_StatsTextEdit">
         <property name="font">
          <font>
           <family>Courier 10 Pitch</family>
          </font>
         </property>
         <property name="acceptDrops">
          <bool>false</bool>
         </property>
         <property name="readOnly">
          <bool>true</bool>
         </property>
        </widget>
       </item>
      </layout>
     </widget>
    </item>
    <item row="2" column="0">
     <spacer name="verticalSpacer">
      <property name="orientation">
       <enum>Qt::Vertical</enum>
      </property>
      <property name="sizeHint" stdset="0">
       <size>
        <width>20</width>
        <height>40</height>
       </size>
      </property>
     </spacer>
    </item>
    <item row="0" column="0">
     <widget class="QGroupBox" name="groupBox_2">
      <property name="title">
       <string>Fiber Processing</string>
      </property>
      <layout class="QFormLayout" name="formLayout">
       <property name="fieldGrowthPolicy">
        <enum>QFormLayout::AllNonFixedFieldsGrow</enum>
       </property>
       <item row="3" column="0">
        <widget class="QCommandLinkButton" name="m_ProcessFiberBundleButton">
         <property name="enabled">
          <bool>false</bool>
         </property>
         <property name="sizePolicy">
          <sizepolicy hsizetype="Preferred" vsizetype="Preferred">
           <horstretch>0</horstretch>
           <verstretch>0</verstretch>
          </sizepolicy>
         </property>
         <property name="maximumSize">
          <size>
           <width>200</width>
           <height>16777215</height>
          </size>
         </property>
         <property name="font">
          <font>
           <pointsize>11</pointsize>
          </font>
         </property>
         <property name="toolTip">
          <string>Perform selected operation on all selected fiber bundles.</string>
         </property>
         <property name="text">
          <string>Generate Image</string>
         </property>
        </widget>
       </item>
       <item row="3" column="1">
        <widget class="QFrame" name="frame_4">
         <property name="frameShape">
          <enum>QFrame::NoFrame</enum>
         </property>
         <property name="frameShadow">
          <enum>QFrame::Raised</enum>
         </property>
         <property name="lineWidth">
          <number>0</number>
         </property>
         <layout class="QGridLayout" name="gridLayout_8">
-         <property name="verticalSpacing">
+         <property name="leftMargin">
+          <number>0</number>
+         </property>
+         <property name="topMargin">
+          <number>0</number>
+         </property>
+         <property name="rightMargin">
           <number>0</number>
          </property>
-         <property name="margin">
+         <property name="bottomMargin">
+          <number>0</number>
+         </property>
+         <property name="verticalSpacing">
           <number>0</number>
          </property>
          <item row="0" column="0">
           <widget class="QComboBox" name="m_GenerationBox">
            <property name="sizePolicy">
             <sizepolicy hsizetype="Expanding" vsizetype="Fixed">
              <horstretch>0</horstretch>
              <verstretch>0</verstretch>
             </sizepolicy>
            </property>
            <item>
             <property name="text">
              <string>Tract Density Image (TDI)</string>
             </property>
            </item>
            <item>
             <property name="text">
              <string>Normalized TDI</string>
             </property>
            </item>
            <item>
             <property name="text">
              <string>Binary Envelope</string>
             </property>
            </item>
            <item>
             <property name="text">
              <string>Fiber Bundle Image</string>
             </property>
            </item>
            <item>
             <property name="text">
              <string>Fiber Endings Image</string>
             </property>
            </item>
            <item>
             <property name="text">
              <string>Fiber Endings Pointset</string>
             </property>
            </item>
           </widget>
          </item>
          <item row="0" column="1">
           <widget class="QDoubleSpinBox" name="m_UpsamplingSpinBox">
            <property name="toolTip">
             <string>Upsampling factor</string>
            </property>
            <property name="decimals">
             <number>1</number>
            </property>
            <property name="minimum">
             <double>0.100000000000000</double>
            </property>
            <property name="maximum">
             <double>10.000000000000000</double>
            </property>
            <property name="singleStep">
             <double>0.100000000000000</double>
            </property>
            <property name="value">
             <double>1.000000000000000</double>
            </property>
           </widget>
          </item>
         </layout>
        </widget>
       </item>
       <item row="4" column="0">
        <widget class="QCommandLinkButton" name="m_ResampleFibersButton">
         <property name="enabled">
          <bool>false</bool>
         </property>
         <property name="sizePolicy">
          <sizepolicy hsizetype="Preferred" vsizetype="Preferred">
           <horstretch>0</horstretch>
           <verstretch>0</verstretch>
          </sizepolicy>
         </property>
         <property name="maximumSize">
          <size>
           <width>200</width>
           <height>16777215</height>
          </size>
         </property>
         <property name="font">
          <font>
           <pointsize>11</pointsize>
          </font>
         </property>
         <property name="toolTip">
          <string>Resample fibers using a Kochanek spline interpolation.</string>
         </property>
         <property name="text">
          <string>Smooth Fibers</string>
         </property>
        </widget>
       </item>
-      <item row="5" column="0">
+      <item row="6" column="0">
        <widget class="QCommandLinkButton" name="m_PruneFibersButton">
         <property name="enabled">
          <bool>false</bool>
         </property>
         <property name="sizePolicy">
          <sizepolicy hsizetype="Preferred" vsizetype="Preferred">
           <horstretch>0</horstretch>
           <verstretch>0</verstretch>
          </sizepolicy>
         </property>
         <property name="maximumSize">
          <size>
           <width>200</width>
           <height>16777215</height>
          </size>
         </property>
         <property name="font">
          <font>
           <pointsize>11</pointsize>
          </font>
         </property>
         <property name="toolTip">
          <string>Remove fibers shorter/longer than the specified length (in mm).</string>
         </property>
         <property name="text">
          <string>Length Threshold</string>
         </property>
        </widget>
       </item>
-      <item row="5" column="1">
+      <item row="6" column="1">
        <widget class="QFrame" name="frame">
         <property name="frameShape">
          <enum>QFrame::NoFrame</enum>
         </property>
         <property name="frameShadow">
          <enum>QFrame::Raised</enum>
         </property>
         <layout class="QGridLayout" name="gridLayout_6">
-         <property name="margin">
+         <property name="leftMargin">
+          <number>0</number>
+         </property>
+         <property name="topMargin">
+          <number>0</number>
+         </property>
+         <property name="rightMargin">
+          <number>0</number>
+         </property>
+         <property name="bottomMargin">
           <number>0</number>
          </property>
          <property name="spacing">
           <number>0</number>
          </property>
          <item row="0" column="0">
           <widget class="QSpinBox" name="m_PruneFibersSpinBox">
            <property name="toolTip">
             <string>Minimum fiber length in mm</string>
            </property>
            <property name="minimum">
             <number>0</number>
            </property>
            <property name="maximum">
             <number>1000</number>
            </property>
            <property name="value">
             <number>20</number>
            </property>
           </widget>
          </item>
          <item row="0" column="1">
           <widget class="QSpinBox" name="m_MaxPruneFibersSpinBox">
            <property name="toolTip">
             <string>Maximum fiber length in mm</string>
            </property>
            <property name="minimum">
             <number>0</number>
            </property>
            <property name="maximum">
             <number>10000</number>
            </property>
            <property name="value">
             <number>500</number>
            </property>
           </widget>
          </item>
         </layout>
        </widget>
       </item>
-      <item row="6" column="0">
+      <item row="7" column="0">
        <widget class="QCommandLinkButton" name="m_CurvatureThresholdButton">
         <property name="enabled">
          <bool>false</bool>
         </property>
         <property name="sizePolicy">
          <sizepolicy hsizetype="Preferred" vsizetype="Preferred">
           <horstretch>0</horstretch>
           <verstretch>0</verstretch>
          </sizepolicy>
         </property>
         <property name="maximumSize">
          <size>
           <width>200</width>
           <height>16777215</height>
          </size>
         </property>
         <property name="font">
          <font>
           <pointsize>11</pointsize>
          </font>
         </property>
         <property name="toolTip">
          <string>Remove fibers with a too high curvature</string>
         </property>
         <property name="text">
          <string>Curvature Threshold</string>
         </property>
        </widget>
       </item>
-      <item row="6" column="1">
+      <item row="7" column="1">
        <widget class="QFrame" name="frame_3">
         <property name="frameShape">
          <enum>QFrame::NoFrame</enum>
         </property>
         <property name="frameShadow">
          <enum>QFrame::Raised</enum>
         </property>
         <layout class="QGridLayout" name="gridLayout_7">
+         <property name="leftMargin">
+          <number>0</number>
+         </property>
+         <property name="topMargin">
+          <number>0</number>
+         </property>
+         <property name="rightMargin">
+          <number>0</number>
+         </property>
+         <property name="bottomMargin">
+          <number>0</number>
+         </property>
          <property name="horizontalSpacing">
           <number>6</number>
          </property>
          <property name="verticalSpacing">
           <number>0</number>
          </property>
-         <property name="margin">
-          <number>0</number>
-         </property>
          <item row="0" column="0">
           <widget class="QDoubleSpinBox" name="m_MinCurvatureRadiusBox">
            <property name="toolTip">
             <string>Minimum radius of circle created by three consecutive points of a fiber</string>
            </property>
            <property name="maximum">
             <double>100.000000000000000</double>
            </property>
            <property name="singleStep">
             <double>0.100000000000000</double>
            </property>
            <property name="value">
             <double>2.000000000000000</double>
            </property>
           </widget>
          </item>
          <item row="0" column="1">
           <widget class="QCheckBox" name="m_RemoveFiberDueToCurvatureCheckbox">
            <property name="toolTip">
             <string>Remove whole fiber if it is exceeding the curvature threshold, otherwise remove only high curvature part.</string>
            </property>
            <property name="text">
             <string>Remove Fiber</string>
            </property>
            <property name="checked">
             <bool>true</bool>
            </property>
           </widget>
          </item>
         </layout>
        </widget>
       </item>
-      <item row="8" column="0">
+      <item row="9" column="0">
        <widget class="QCommandLinkButton" name="m_MirrorFibersButton">
         <property name="enabled">
          <bool>false</bool>
         </property>
         <property name="sizePolicy">
          <sizepolicy hsizetype="Preferred" vsizetype="Preferred">
           <horstretch>0</horstretch>
           <verstretch>0</verstretch>
          </sizepolicy>
         </property>
         <property name="maximumSize">
          <size>
           <width>200</width>
           <height>16777215</height>
          </size>
         </property>
         <property name="font">
          <font>
           <pointsize>11</pointsize>
          </font>
         </property>
         <property name="toolTip">
          <string>Mirror fibers around specified axis.</string>
         </property>
         <property name="text">
          <string>Mirror Fibers</string>
         </property>
        </widget>
       </item>
-      <item row="8" column="1">
+      <item row="9" column="1">
        <widget class="QComboBox" name="m_AxisSelectionBox">
         <property name="currentIndex">
          <number>0</number>
         </property>
         <property name="maxVisibleItems">
          <number>3</number>
         </property>
         <property name="maxCount">
          <number>3</number>
         </property>
         <item>
          <property name="text">
           <string>Sagittal</string>
          </property>
         </item>
         <item>
          <property name="text">
           <string>Coronal</string>
          </property>
         </item>
         <item>
          <property name="text">
           <string>Axial</string>
          </property>
         </item>
        </widget>
       </item>
-      <item row="9" column="0">
+      <item row="10" column="0">
        <widget class="QCommandLinkButton" name="m_FaColorFibersButton">
         <property name="enabled">
          <bool>false</bool>
         </property>
         <property name="sizePolicy">
          <sizepolicy hsizetype="Preferred" vsizetype="Preferred">
           <horstretch>0</horstretch>
           <verstretch>0</verstretch>
          </sizepolicy>
         </property>
         <property name="maximumSize">
          <size>
           <width>200</width>
           <height>16777215</height>
          </size>
         </property>
         <property name="font">
          <font>
           <pointsize>11</pointsize>
          </font>
         </property>
         <property name="toolTip">
          <string>Apply float image values (0-1) as color coding to the selected fiber bundle.</string>
         </property>
         <property name="text">
          <string>Color By Scalar Map</string>
         </property>
        </widget>
       </item>
       <item row="4" column="1">
        <widget class="QDoubleSpinBox" name="m_ResampleFibersSpinBox">
         <property name="toolTip">
          <string>Fiber point distance in mm</string>
         </property>
         <property name="decimals">
          <number>1</number>
         </property>
         <property name="minimum">
          <double>0.100000000000000</double>
         </property>
         <property name="singleStep">
          <double>0.100000000000000</double>
         </property>
         <property name="value">
          <double>1.000000000000000</double>
         </property>
        </widget>
       </item>
+      <item row="5" column="0">
+       <widget class="QCommandLinkButton" name="m_CompressFibersButton">
+        <property name="enabled">
+         <bool>false</bool>
+        </property>
+        <property name="sizePolicy">
+         <sizepolicy hsizetype="Preferred" vsizetype="Preferred">
+          <horstretch>0</horstretch>
+          <verstretch>0</verstretch>
+         </sizepolicy>
+        </property>
+        <property name="maximumSize">
+         <size>
+          <width>200</width>
+          <height>16777215</height>
+         </size>
+        </property>
+        <property name="font">
+         <font>
+          <pointsize>11</pointsize>
+         </font>
+        </property>
+        <property name="toolTip">
+         <string>Remove points from fibers with the specified error constraint.</string>
+        </property>
+        <property name="text">
+         <string>Compress Fibers</string>
+        </property>
+       </widget>
+      </item>
+      <item row="5" column="1">
+       <widget class="QDoubleSpinBox" name="m_FiberErrorSpinBox">
+        <property name="toolTip">
+         <string>Allowed error in mm.</string>
+        </property>
+        <property name="decimals">
+         <number>3</number>
+        </property>
+        <property name="minimum">
+         <double>0.000000000000000</double>
+        </property>
+        <property name="maximum">
+         <double>10.000000000000000</double>
+        </property>
+        <property name="singleStep">
+         <double>0.010000000000000</double>
+        </property>
+        <property name="value">
+         <double>0.100000000000000</double>
+        </property>
+       </widget>
+      </item>
      </layout>
     </widget>
    </item>
   </layout>
  </widget>
  <resources/>
  <connections/>
 </ui>
diff --git a/Plugins/org.mitk.gui.qt.diffusionimaging/src/internal/QmitkStreamlineTrackingView.cpp b/Plugins/org.mitk.gui.qt.diffusionimaging/src/internal/QmitkStreamlineTrackingView.cpp
index 9a249e3623..039a40fd5f 100644
--- a/Plugins/org.mitk.gui.qt.diffusionimaging/src/internal/QmitkStreamlineTrackingView.cpp
+++ b/Plugins/org.mitk.gui.qt.diffusionimaging/src/internal/QmitkStreamlineTrackingView.cpp
@@ -1,285 +1,286 @@
 /*===================================================================
 
 The Medical Imaging Interaction Toolkit (MITK)
 
 Copyright (c) German Cancer Research Center,
 Division of Medical and Biological Informatics.
 All rights reserved.
 
 This software is distributed WITHOUT ANY WARRANTY; without
 even the implied warranty of MERCHANTABILITY or FITNESS FOR
 A PARTICULAR PURPOSE.
 
 See LICENSE.txt or http://www.mitk.org for details.
 
 ===================================================================*/
 
 
 // Blueberry
 #include <berryISelectionService.h>
 #include <berryIWorkbenchWindow.h>
 #include <berryIStructuredSelection.h>
 
 // Qmitk
 #include "QmitkStreamlineTrackingView.h"
 #include "QmitkStdMultiWidget.h"
 
 // Qt
 #include <QMessageBox>
 
 // MITK
 #include <mitkImageToItk.h>
 #include <mitkFiberBundleX.h>
 #include <mitkImageCast.h>
 #include <mitkNodePredicateDataType.h>
 #include <mitkNodePredicateNot.h>
 #include <mitkNodePredicateAnd.h>
 #include <mitkNodePredicateProperty.h>
 #include <mitkNodePredicateDimension.h>
 
 // VTK
 #include <vtkPolyData.h>
 #include <vtkPoints.h>
 #include <vtkCellArray.h>
 #include <vtkSmartPointer.h>
 #include <vtkPolyLine.h>
 #include <vtkCellData.h>
 
 
 const std::string QmitkStreamlineTrackingView::VIEW_ID = "org.mitk.views.streamlinetracking";
 const std::string id_DataManager = "org.mitk.views.datamanager";
 using namespace berry;
 
 QmitkStreamlineTrackingView::QmitkStreamlineTrackingView()
     : QmitkFunctionality()
     , m_Controls( 0 )
     , m_MultiWidget( NULL )
     , m_MaskImage( NULL )
     , m_SeedRoi( NULL )
 {
 }
 
 // Destructor
 QmitkStreamlineTrackingView::~QmitkStreamlineTrackingView()
 {
 
 }
 
 void QmitkStreamlineTrackingView::CreateQtPartControl( QWidget *parent )
 {
     if ( !m_Controls )
     {
         // create GUI widgets from the Qt Designer's .ui file
         m_Controls = new Ui::QmitkStreamlineTrackingViewControls;
         m_Controls->setupUi( parent );
         m_Controls->m_FaImageBox->SetDataStorage(this->GetDataStorage());
 
         mitk::TNodePredicateDataType<mitk::Image>::Pointer isImagePredicate = mitk::TNodePredicateDataType<mitk::Image>::New();
 
         mitk::NodePredicateProperty::Pointer isBinaryPredicate = mitk::NodePredicateProperty::New("binary", mitk::BoolProperty::New(true));
         mitk::NodePredicateNot::Pointer isNotBinaryPredicate = mitk::NodePredicateNot::New( isBinaryPredicate );
         mitk::NodePredicateAnd::Pointer isNotABinaryImagePredicate = mitk::NodePredicateAnd::New( isImagePredicate, isNotBinaryPredicate );
         mitk::NodePredicateDimension::Pointer dimensionPredicate = mitk::NodePredicateDimension::New(3);
 
         m_Controls->m_FaImageBox->SetPredicate( mitk::NodePredicateAnd::New(isNotABinaryImagePredicate, dimensionPredicate) );
 
         connect( m_Controls->commandLinkButton, SIGNAL(clicked()), this, SLOT(DoFiberTracking()) );
         connect( m_Controls->m_SeedsPerVoxelSlider, SIGNAL(valueChanged(int)), this, SLOT(OnSeedsPerVoxelChanged(int)) );
         connect( m_Controls->m_MinTractLengthSlider, SIGNAL(valueChanged(int)), this, SLOT(OnMinTractLengthChanged(int)) );
         connect( m_Controls->m_FaThresholdSlider, SIGNAL(valueChanged(int)), this, SLOT(OnFaThresholdChanged(int)) );
         connect( m_Controls->m_AngularThresholdSlider, SIGNAL(valueChanged(int)), this, SLOT(OnAngularThresholdChanged(int)) );
         connect( m_Controls->m_StepsizeSlider, SIGNAL(valueChanged(int)), this, SLOT(OnStepsizeChanged(int)) );
         connect( m_Controls->m_fSlider, SIGNAL(valueChanged(int)), this, SLOT(OnfChanged(int)) );
         connect( m_Controls->m_gSlider, SIGNAL(valueChanged(int)), this, SLOT(OngChanged(int)) );
     }
 }
 
 void QmitkStreamlineTrackingView::OnfChanged(int value)
 {
     m_Controls->m_fLabel->setText(QString("f: ")+QString::number((float)value/100));
 }
 
 void QmitkStreamlineTrackingView::OngChanged(int value)
 {
     m_Controls->m_gLabel->setText(QString("g: ")+QString::number((float)value/100));
 }
 
 void QmitkStreamlineTrackingView::OnAngularThresholdChanged(int value)
 {
     if (value<0)
         m_Controls->m_AngularThresholdLabel->setText(QString("Min. Curvature Radius: auto"));
     else
         m_Controls->m_AngularThresholdLabel->setText(QString("Min. Curvature Radius: ")+QString::number((float)value/10)+QString("mm"));
 }
 
 void QmitkStreamlineTrackingView::OnSeedsPerVoxelChanged(int value)
 {
     m_Controls->m_SeedsPerVoxelLabel->setText(QString("Seeds per Voxel: ")+QString::number(value));
 }
 
 void QmitkStreamlineTrackingView::OnMinTractLengthChanged(int value)
 {
     m_Controls->m_MinTractLengthLabel->setText(QString("Min. Tract Length: ")+QString::number(value)+QString("mm"));
 }
 
 void QmitkStreamlineTrackingView::OnFaThresholdChanged(int value)
 {
     m_Controls->m_FaThresholdLabel->setText(QString("FA Threshold: ")+QString::number((float)value/100));
 }
 
 void QmitkStreamlineTrackingView::OnStepsizeChanged(int value)
 {
     if (value==0)
         m_Controls->m_StepsizeLabel->setText(QString("Stepsize: auto"));
     else
         m_Controls->m_StepsizeLabel->setText(QString("Stepsize: ")+QString::number((float)value/10)+QString("mm"));
 }
 
 void QmitkStreamlineTrackingView::StdMultiWidgetAvailable (QmitkStdMultiWidget &stdMultiWidget)
 {
     m_MultiWidget = &stdMultiWidget;
 }
 
 
 void QmitkStreamlineTrackingView::StdMultiWidgetNotAvailable()
 {
     m_MultiWidget = NULL;
 }
 
 void QmitkStreamlineTrackingView::OnSelectionChanged( std::vector<mitk::DataNode*> nodes )
 {
     m_TensorImageNodes.clear();
     m_TensorImages.clear();
     m_SeedRoi = NULL;
     m_MaskImage = NULL;
     m_Controls->m_TensorImageLabel->setText("<font color='red'>mandatory</font>");
     m_Controls->m_RoiImageLabel->setText("<font color='grey'>optional</font>");
     m_Controls->m_MaskImageLabel->setText("<font color='grey'>optional</font>");
 
     for( std::vector<mitk::DataNode*>::iterator it = nodes.begin(); it != nodes.end(); ++it )
     {
         mitk::DataNode::Pointer node = *it;
 
         if( node.IsNotNull() && dynamic_cast<mitk::Image*>(node->GetData()) )
         {
             if( dynamic_cast<mitk::TensorImage*>(node->GetData()) )
             {
                 m_TensorImageNodes.push_back(node);
                 m_TensorImages.push_back(dynamic_cast<mitk::TensorImage*>(node->GetData()));
             }
             else
             {
                 bool isBinary = false;
                 node->GetPropertyValue<bool>("binary", isBinary);
                 if (isBinary && m_SeedRoi.IsNull())
                 {
                     m_SeedRoi = dynamic_cast<mitk::Image*>(node->GetData());
                     m_Controls->m_RoiImageLabel->setText(node->GetName().c_str());
                 }
                 else if (isBinary)
                 {
                     m_MaskImage = dynamic_cast<mitk::Image*>(node->GetData());
                     m_Controls->m_MaskImageLabel->setText(node->GetName().c_str());
                 }
             }
         }
     }
 
     if(!m_TensorImageNodes.empty())
     {
         if (m_TensorImageNodes.size()>1)
             m_Controls->m_TensorImageLabel->setText(m_TensorImageNodes.size()+" tensor images selected");
         else
             m_Controls->m_TensorImageLabel->setText(m_TensorImageNodes.at(0)->GetName().c_str());
         m_Controls->m_InputData->setTitle("Input Data");
         m_Controls->commandLinkButton->setEnabled(true);
     }
     else
     {
         m_Controls->m_InputData->setTitle("Please Select Input Data");
         m_Controls->commandLinkButton->setEnabled(false);
     }
 }
 
 
 
 void QmitkStreamlineTrackingView::DoFiberTracking()
 {
     if (m_TensorImages.empty())
         return;
 
     typedef itk::Image< itk::DiffusionTensor3D<float>, 3> TensorImageType;
     typedef mitk::ImageToItk<TensorImageType> CastType;
     typedef mitk::ImageToItk<ItkUCharImageType> CastType2;
 
     typedef itk::StreamlineTrackingFilter< float > FilterType;
     FilterType::Pointer filter = FilterType::New();
 
     for (int i=0; i<(int)m_TensorImages.size(); i++)
     {
         CastType::Pointer caster = CastType::New();
         caster->SetInput(m_TensorImages.at(i));
         caster->Update();
         filter->SetInput(i, caster->GetOutput());
     }
 
     if (m_Controls->m_UseFaImage->isChecked())
     {
         mitk::ImageToItk<ItkFloatImageType>::Pointer floatCast = mitk::ImageToItk<ItkFloatImageType>::New();
         floatCast->SetInput(dynamic_cast<mitk::Image*>(m_Controls->m_FaImageBox->GetSelectedNode()->GetData()));
         floatCast->Update();
         filter->SetFaImage(floatCast->GetOutput());
     }
 
     //filter->SetNumberOfThreads(1);
     filter->SetSeedsPerVoxel(m_Controls->m_SeedsPerVoxelSlider->value());
     filter->SetFaThreshold((float)m_Controls->m_FaThresholdSlider->value()/100);
     filter->SetMinCurvatureRadius((float)m_Controls->m_AngularThresholdSlider->value()/10);
     filter->SetStepSize((float)m_Controls->m_StepsizeSlider->value()/10);
     filter->SetF((float)m_Controls->m_fSlider->value()/100);
     filter->SetG((float)m_Controls->m_gSlider->value()/100);
     filter->SetInterpolate(m_Controls->m_InterpolationBox->isChecked());
     filter->SetMinTractLength(m_Controls->m_MinTractLengthSlider->value());
-    filter->SetResampleFibers(m_Controls->m_ResampleFibersBox->isChecked());
 
     if (m_SeedRoi.IsNotNull())
     {
         ItkUCharImageType::Pointer mask = ItkUCharImageType::New();
         mitk::CastToItkImage<ItkUCharImageType>(m_SeedRoi, mask);
         filter->SetSeedImage(mask);
     }
 
     if (m_MaskImage.IsNotNull())
     {
         ItkUCharImageType::Pointer mask = ItkUCharImageType::New();
         mitk::CastToItkImage<ItkUCharImageType>(m_MaskImage, mask);
         filter->SetMaskImage(mask);
     }
 
     filter->Update();
 
     vtkSmartPointer<vtkPolyData> fiberBundle = filter->GetFiberPolyData();
     if ( fiberBundle->GetNumberOfLines()==0 )
     {
         QMessageBox warnBox;
         warnBox.setWindowTitle("Warning");
         warnBox.setText("No fiberbundle was generated!");
         warnBox.setDetailedText("No fibers were generated using the parameters: \n\n" + m_Controls->m_FaThresholdLabel->text() + "\n" + m_Controls->m_AngularThresholdLabel->text() + "\n" + m_Controls->m_fLabel->text() + "\n" + m_Controls->m_gLabel->text() + "\n" + m_Controls->m_StepsizeLabel->text() + "\n" + m_Controls->m_MinTractLengthLabel->text() + "\n" + m_Controls->m_SeedsPerVoxelLabel->text() + "\n\nPlease check your parametersettings.");
         warnBox.setIcon(QMessageBox::Warning);
         warnBox.exec();
         return;
     }
     mitk::FiberBundleX::Pointer fib = mitk::FiberBundleX::New(fiberBundle);
     fib->SetReferenceImage(dynamic_cast<mitk::Image*>(m_TensorImageNodes.at(0)->GetData()));
+    if (m_Controls->m_ResampleFibersBox->isChecked())
+        fib->CompressFibers(m_Controls->m_FiberErrorBox->value());
 
     mitk::DataNode::Pointer node = mitk::DataNode::New();
     node->SetData(fib);
     QString name("FiberBundle_");
     name += m_TensorImageNodes.at(0)->GetName().c_str();
     name += "_Streamline";
     node->SetName(name.toStdString());
     node->SetVisibility(true);
     GetDataStorage()->Add(node, m_TensorImageNodes.at(0));
 }
 
 
diff --git a/Plugins/org.mitk.gui.qt.diffusionimaging/src/internal/QmitkStreamlineTrackingViewControls.ui b/Plugins/org.mitk.gui.qt.diffusionimaging/src/internal/QmitkStreamlineTrackingViewControls.ui
index 2a0bb579b7..b314c425aa 100644
--- a/Plugins/org.mitk.gui.qt.diffusionimaging/src/internal/QmitkStreamlineTrackingViewControls.ui
+++ b/Plugins/org.mitk.gui.qt.diffusionimaging/src/internal/QmitkStreamlineTrackingViewControls.ui
@@ -1,412 +1,431 @@
 <?xml version="1.0" encoding="UTF-8"?>
 <ui version="4.0">
  <class>QmitkStreamlineTrackingViewControls</class>
  <widget class="QWidget" name="QmitkStreamlineTrackingViewControls">
   <property name="geometry">
    <rect>
     <x>0</x>
     <y>0</y>
     <width>382</width>
     <height>538</height>
    </rect>
   </property>
   <property name="minimumSize">
    <size>
     <width>0</width>
     <height>0</height>
    </size>
   </property>
   <property name="windowTitle">
    <string>QmitkTemplate</string>
   </property>
   <layout class="QGridLayout" name="gridLayout_3">
    <property name="topMargin">
     <number>3</number>
    </property>
    <property name="bottomMargin">
     <number>3</number>
    </property>
    <property name="spacing">
     <number>0</number>
    </property>
    <item row="8" column="0">
     <spacer name="spacer1">
      <property name="orientation">
       <enum>Qt::Vertical</enum>
      </property>
      <property name="sizeType">
       <enum>QSizePolicy::Expanding</enum>
      </property>
      <property name="sizeHint" stdset="0">
       <size>
        <width>20</width>
        <height>220</height>
       </size>
      </property>
     </spacer>
    </item>
    <item row="1" column="0">
     <widget class="QCommandLinkButton" name="commandLinkButton">
      <property name="enabled">
       <bool>false</bool>
      </property>
      <property name="text">
       <string>Start Tractography</string>
      </property>
     </widget>
    </item>
    <item row="5" column="0">
     <widget class="QGroupBox" name="groupBox_2">
      <property name="title">
       <string>Parameters</string>
      </property>
      <layout class="QGridLayout" name="gridLayout_2">
-      <item row="3" column="0">
-       <widget class="QLabel" name="m_fLabel">
+      <item row="4" column="1">
+       <widget class="QSlider" name="m_gSlider">
         <property name="toolTip">
-         <string/>
+         <string>Weighting factor between input vector (g=0) and tensor deflection (g=1 equals TEND tracking)</string>
         </property>
-        <property name="text">
-         <string>f: 1</string>
+        <property name="minimum">
+         <number>0</number>
         </property>
-       </widget>
-      </item>
-      <item row="4" column="0">
-       <widget class="QLabel" name="m_gLabel">
-        <property name="toolTip">
-         <string/>
+        <property name="maximum">
+         <number>100</number>
         </property>
-        <property name="text">
-         <string>g: 0</string>
+        <property name="value">
+         <number>0</number>
         </property>
-       </widget>
-      </item>
-      <item row="8" column="0">
-       <spacer name="horizontalSpacer">
         <property name="orientation">
          <enum>Qt::Horizontal</enum>
         </property>
-        <property name="sizeType">
-         <enum>QSizePolicy::Fixed</enum>
-        </property>
-        <property name="sizeHint" stdset="0">
-         <size>
-          <width>200</width>
-          <height>0</height>
-         </size>
-        </property>
-       </spacer>
-      </item>
-      <item row="5" column="0">
-       <widget class="QLabel" name="m_StepsizeLabel">
-        <property name="toolTip">
-         <string/>
-        </property>
-        <property name="text">
-         <string>Step Size: auto</string>
-        </property>
        </widget>
       </item>
-      <item row="3" column="1">
-       <widget class="QSlider" name="m_fSlider">
+      <item row="5" column="1">
+       <widget class="QSlider" name="m_StepsizeSlider">
         <property name="toolTip">
-         <string>Weighting factor between first eigenvector (f=1 equals FACT tracking) and input vector dependent direction (f=0).</string>
+         <string>Stepsize in mm (auto = 0.1*minimal spacing)</string>
         </property>
         <property name="minimum">
          <number>0</number>
         </property>
         <property name="maximum">
          <number>100</number>
         </property>
         <property name="value">
-         <number>100</number>
+         <number>0</number>
         </property>
         <property name="orientation">
          <enum>Qt::Horizontal</enum>
         </property>
        </widget>
       </item>
-      <item row="5" column="1">
-       <widget class="QSlider" name="m_StepsizeSlider">
+      <item row="2" column="1">
+       <widget class="QSlider" name="m_AngularThresholdSlider">
         <property name="toolTip">
-         <string>Stepsize in mm (auto = 0.1*minimal spacing)</string>
+         <string>Minimally allowed curcature radius (in mm, interpolated auto = 0.5 minimal spacing, noninterpolated auto = 0.1 minimal spacing)</string>
         </property>
         <property name="minimum">
-         <number>0</number>
+         <number>-1</number>
         </property>
         <property name="maximum">
-         <number>100</number>
+         <number>50</number>
         </property>
         <property name="value">
-         <number>0</number>
+         <number>-1</number>
         </property>
         <property name="orientation">
          <enum>Qt::Horizontal</enum>
         </property>
        </widget>
       </item>
+      <item row="6" column="0">
+       <widget class="QLabel" name="m_MinTractLengthLabel">
+        <property name="toolTip">
+         <string/>
+        </property>
+        <property name="text">
+         <string>Min. Tract Length: 40mm</string>
+        </property>
+       </widget>
+      </item>
       <item row="1" column="0">
        <widget class="QLabel" name="m_FaThresholdLabel">
         <property name="toolTip">
          <string/>
         </property>
         <property name="text">
          <string>FA Threshold: 0.2</string>
         </property>
        </widget>
       </item>
-      <item row="4" column="1">
-       <widget class="QSlider" name="m_gSlider">
+      <item row="4" column="0">
+       <widget class="QLabel" name="m_gLabel">
         <property name="toolTip">
-         <string>Weighting factor between input vector (g=0) and tensor deflection (g=1 equals TEND tracking)</string>
-        </property>
-        <property name="minimum">
-         <number>0</number>
-        </property>
-        <property name="maximum">
-         <number>100</number>
+         <string/>
         </property>
-        <property name="value">
-         <number>0</number>
+        <property name="text">
+         <string>g: 0</string>
         </property>
+       </widget>
+      </item>
+      <item row="8" column="0">
+       <spacer name="horizontalSpacer">
         <property name="orientation">
          <enum>Qt::Horizontal</enum>
         </property>
-       </widget>
+        <property name="sizeType">
+         <enum>QSizePolicy::Fixed</enum>
+        </property>
+        <property name="sizeHint" stdset="0">
+         <size>
+          <width>200</width>
+          <height>0</height>
+         </size>
+        </property>
+       </spacer>
       </item>
       <item row="7" column="0">
        <widget class="QLabel" name="m_SeedsPerVoxelLabel">
         <property name="toolTip">
          <string/>
         </property>
         <property name="text">
          <string>Seeds per Voxel: 1</string>
         </property>
        </widget>
       </item>
       <item row="7" column="1">
        <widget class="QSlider" name="m_SeedsPerVoxelSlider">
         <property name="toolTip">
          <string>Number of tracts started in each voxel of the seed ROI.</string>
         </property>
         <property name="minimum">
          <number>1</number>
         </property>
         <property name="maximum">
          <number>100</number>
         </property>
         <property name="orientation">
          <enum>Qt::Horizontal</enum>
         </property>
        </widget>
       </item>
-      <item row="9" column="0">
-       <widget class="QCheckBox" name="m_InterpolationBox">
+      <item row="5" column="0">
+       <widget class="QLabel" name="m_StepsizeLabel">
         <property name="toolTip">
-         <string>Default is nearest neighbor interpolation.</string>
+         <string/>
         </property>
         <property name="text">
-         <string>Enable trilinear interpolation</string>
-        </property>
-        <property name="checked">
-         <bool>false</bool>
+         <string>Step Size: auto</string>
         </property>
        </widget>
       </item>
-      <item row="2" column="1">
-       <widget class="QSlider" name="m_AngularThresholdSlider">
+      <item row="3" column="1">
+       <widget class="QSlider" name="m_fSlider">
         <property name="toolTip">
-         <string>Minimally allowed curcature radius (in mm, interpolated auto = 0.5 minimal spacing, noninterpolated auto = 0.1 minimal spacing)</string>
+         <string>Weighting factor between first eigenvector (f=1 equals FACT tracking) and input vector dependent direction (f=0).</string>
         </property>
         <property name="minimum">
-         <number>-1</number>
+         <number>0</number>
         </property>
         <property name="maximum">
-         <number>50</number>
+         <number>100</number>
         </property>
         <property name="value">
-         <number>-1</number>
+         <number>100</number>
         </property>
         <property name="orientation">
          <enum>Qt::Horizontal</enum>
         </property>
        </widget>
       </item>
-      <item row="6" column="0">
-       <widget class="QLabel" name="m_MinTractLengthLabel">
-        <property name="toolTip">
-         <string/>
-        </property>
-        <property name="text">
-         <string>Min. Tract Length: 40mm</string>
-        </property>
-       </widget>
-      </item>
       <item row="1" column="1">
        <widget class="QSlider" name="m_FaThresholdSlider">
         <property name="toolTip">
          <string>Fractional Anisotropy Threshold</string>
         </property>
         <property name="minimum">
          <number>0</number>
         </property>
         <property name="maximum">
          <number>100</number>
         </property>
         <property name="value">
          <number>20</number>
         </property>
         <property name="orientation">
          <enum>Qt::Horizontal</enum>
         </property>
        </widget>
       </item>
       <item row="6" column="1">
        <widget class="QSlider" name="m_MinTractLengthSlider">
         <property name="toolTip">
          <string>Minimum tract length in mm.</string>
         </property>
         <property name="minimum">
          <number>0</number>
         </property>
         <property name="maximum">
          <number>500</number>
         </property>
         <property name="value">
          <number>40</number>
         </property>
         <property name="orientation">
          <enum>Qt::Horizontal</enum>
         </property>
        </widget>
       </item>
+      <item row="9" column="0">
+       <widget class="QCheckBox" name="m_InterpolationBox">
+        <property name="toolTip">
+         <string>Default is nearest neighbor interpolation.</string>
+        </property>
+        <property name="text">
+         <string>Enable Trilinear Interpolation</string>
+        </property>
+        <property name="checked">
+         <bool>false</bool>
+        </property>
+       </widget>
+      </item>
+      <item row="3" column="0">
+       <widget class="QLabel" name="m_fLabel">
+        <property name="toolTip">
+         <string/>
+        </property>
+        <property name="text">
+         <string>f: 1</string>
+        </property>
+       </widget>
+      </item>
       <item row="2" column="0">
        <widget class="QLabel" name="m_AngularThresholdLabel">
         <property name="toolTip">
          <string/>
         </property>
         <property name="text">
          <string>Min. Curvature Radius: auto</string>
         </property>
        </widget>
       </item>
       <item row="10" column="0">
        <widget class="QCheckBox" name="m_ResampleFibersBox">
         <property name="toolTip">
-         <string>Resample fibers to 0.5*voxel size (recommended for small step sizes to avoid memory issues).</string>
+         <string>Resample fibers using the specified error constraint.</string>
         </property>
         <property name="text">
-         <string>Resample fibers</string>
+         <string>Compress Fibers</string>
         </property>
         <property name="checked">
-         <bool>false</bool>
+         <bool>true</bool>
+        </property>
+       </widget>
+      </item>
+      <item row="10" column="1">
+       <widget class="QDoubleSpinBox" name="m_FiberErrorBox">
+        <property name="toolTip">
+         <string>Maximum error in mm.</string>
+        </property>
+        <property name="decimals">
+         <number>3</number>
+        </property>
+        <property name="maximum">
+         <double>10.000000000000000</double>
+        </property>
+        <property name="singleStep">
+         <double>0.010000000000000</double>
+        </property>
+        <property name="value">
+         <double>0.100000000000000</double>
         </property>
        </widget>
       </item>
      </layout>
     </widget>
    </item>
    <item row="0" column="0">
     <widget class="QGroupBox" name="m_InputData">
      <property name="title">
       <string>Please Select Input Data</string>
      </property>
      <layout class="QGridLayout" name="gridLayout">
       <item row="2" column="1">
        <widget class="QLabel" name="m_MaskImageLabel">
         <property name="text">
          <string>&lt;html&gt;&lt;head/&gt;&lt;body&gt;&lt;p&gt;&lt;span style=&quot; color:#969696;&quot;&gt;optional&lt;/span&gt;&lt;/p&gt;&lt;/body&gt;&lt;/html&gt;</string>
         </property>
         <property name="wordWrap">
          <bool>true</bool>
         </property>
        </widget>
       </item>
       <item row="4" column="1">
        <widget class="QmitkDataStorageComboBox" name="m_FaImageBox">
         <item>
          <property name="text">
           <string>-</string>
          </property>
         </item>
        </widget>
       </item>
       <item row="1" column="1">
        <widget class="QLabel" name="m_RoiImageLabel">
         <property name="text">
          <string>&lt;html&gt;&lt;head/&gt;&lt;body&gt;&lt;p&gt;&lt;span style=&quot; color:#969696;&quot;&gt;optional&lt;/span&gt;&lt;/p&gt;&lt;/body&gt;&lt;/html&gt;</string>
         </property>
         <property name="wordWrap">
          <bool>true</bool>
         </property>
        </widget>
       </item>
       <item row="2" column="0">
        <widget class="QLabel" name="label_7">
         <property name="toolTip">
          <string>Only track insida mask area.</string>
         </property>
         <property name="text">
          <string>Mask Image:</string>
         </property>
        </widget>
       </item>
       <item row="1" column="0">
        <widget class="QLabel" name="label_6">
         <property name="toolTip">
          <string>Binary seed ROI. If not specified, the whole image area is seeded.</string>
         </property>
         <property name="text">
          <string>Seed ROI:</string>
         </property>
        </widget>
       </item>
       <item row="0" column="1">
        <widget class="QLabel" name="m_TensorImageLabel">
         <property name="text">
          <string>&lt;html&gt;&lt;head/&gt;&lt;body&gt;&lt;p&gt;&lt;span style=&quot; color:#ff0000;&quot;&gt;mandatory&lt;/span&gt;&lt;/p&gt;&lt;/body&gt;&lt;/html&gt;</string>
         </property>
         <property name="wordWrap">
          <bool>true</bool>
         </property>
        </widget>
       </item>
       <item row="0" column="0">
        <widget class="QLabel" name="label_2">
         <property name="toolTip">
          <string>Input DTI</string>
         </property>
         <property name="text">
          <string>Tensor Image:</string>
         </property>
        </widget>
       </item>
       <item row="4" column="0">
        <widget class="QCheckBox" name="m_UseFaImage">
         <property name="toolTip">
          <string>Check to use selected FA image instead of internally calculated one. Recommended for multi-tensor tractography.</string>
         </property>
         <property name="text">
          <string>FA image</string>
         </property>
         <property name="checked">
          <bool>false</bool>
         </property>
        </widget>
       </item>
      </layout>
     </widget>
    </item>
   </layout>
  </widget>
  <layoutdefault spacing="6" margin="11"/>
  <customwidgets>
   <customwidget>
    <class>QmitkDataStorageComboBox</class>
    <extends>QComboBox</extends>
    <header location="global">QmitkDataStorageComboBox.h</header>
   </customwidget>
  </customwidgets>
  <resources/>
  <connections/>
 </ui>