diff --git a/Plugins/org.mitk.gui.qt.diffusionimaging/src/internal/QmitkQBallReconstructionView.cpp b/Plugins/org.mitk.gui.qt.diffusionimaging/src/internal/QmitkQBallReconstructionView.cpp
index 279290f66d..24b1b5255b 100644
--- a/Plugins/org.mitk.gui.qt.diffusionimaging/src/internal/QmitkQBallReconstructionView.cpp
+++ b/Plugins/org.mitk.gui.qt.diffusionimaging/src/internal/QmitkQBallReconstructionView.cpp
@@ -1,1081 +1,1076 @@
 /*===================================================================
 
 The Medical Imaging Interaction Toolkit (MITK)
 
 Copyright (c) German Cancer Research Center, 
 Division of Medical and Biological Informatics.
 All rights reserved.
 
 This software is distributed WITHOUT ANY WARRANTY; without 
 even the implied warranty of MERCHANTABILITY or FITNESS FOR 
 A PARTICULAR PURPOSE.
 
 See LICENSE.txt or http://www.mitk.org for details.
 
 ===================================================================*/
 
 //#define MBILOG_ENABLE_DEBUG
 
 #include "QmitkQBallReconstructionView.h"
 #include "mitkDiffusionImagingConfigure.h"
 
 // qt includes
 #include <QMessageBox>
 
 // itk includes
 #include "itkTimeProbe.h"
 
 // mitk includes
 #include "mitkProgressBar.h"
 #include "mitkStatusBar.h"
 
 #include "mitkNodePredicateDataType.h"
 #include "QmitkDataStorageComboBox.h"
 #include "QmitkStdMultiWidget.h"
 
 #include "itkDiffusionQballReconstructionImageFilter.h"
 #include "itkAnalyticalDiffusionQballReconstructionImageFilter.h"
 #include "itkDiffusionMultiShellQballReconstructionImageFilter.h"
 #include "itkVectorContainer.h"
 
 #include "mitkQBallImage.h"
 #include "mitkProperties.h"
 #include "mitkVtkResliceInterpolationProperty.h"
 #include "mitkLookupTable.h"
 #include "mitkLookupTableProperty.h"
 #include "mitkTransferFunction.h"
 #include "mitkTransferFunctionProperty.h"
 #include "mitkDataNodeObject.h"
 #include "mitkOdfNormalizationMethodProperty.h"
 #include "mitkOdfScaleByProperty.h"
 
 #include "berryIStructuredSelection.h"
 #include "berryIWorkbenchWindow.h"
 #include "berryISelectionService.h"
 
 #include <boost/version.hpp>
 
 const std::string QmitkQBallReconstructionView::VIEW_ID =
     "org.mitk.views.qballreconstruction";
 
 #define DI_INFO MITK_INFO("DiffusionImaging")
 
 
 typedef float TTensorPixelType;
 
 const int QmitkQBallReconstructionView::nrconvkernels = 252;
 
 
 struct QbrShellSelection
 {
   QmitkQBallReconstructionView* m_View;
   mitk::DataNode * m_Node;
   std::string m_NodeName;
 
   std::vector<QCheckBox *> m_CheckBoxes;
   QLabel * m_Label;
 
   mitk::DiffusionImage<DiffusionPixelType> * m_Image;
   typedef mitk::DiffusionImage<DiffusionPixelType>::BValueMap  BValueMap;
 
   QbrShellSelection(QmitkQBallReconstructionView* view, mitk::DataNode * node)
     : m_View(view),
       m_Node(node),
       m_NodeName(node->GetName())
   {
     m_Image = dynamic_cast<mitk::DiffusionImage<DiffusionPixelType> * > (node->GetData());
     if(!m_Image){MITK_INFO << "QmitkQBallReconstructionView::QbrShellSelection : fail to initialize DiffusionImage "; return;}
 
     GenerateCheckboxes();
 
   }
 
   void GenerateCheckboxes()
   {
     BValueMap origMap = m_Image->GetB_ValueMap();
     BValueMap::iterator itStart = origMap.begin();
     itStart++;
     BValueMap::iterator itEnd = origMap.end();
 
     m_Label = new QLabel(m_NodeName.c_str());
     m_Label->setVisible(true);
     m_View->m_Controls->m_QBallSelectionBox->layout()->addWidget(m_Label);
 
     for(BValueMap::iterator it = itStart ; it!= itEnd; it++)
     {
       QCheckBox * box  = new QCheckBox(QString::number(it->first));
       m_View->m_Controls->m_QBallSelectionBox->layout()->addWidget(box);
 
       box->setChecked(true);
       box->setCheckable(true);
      // box->setVisible(true);
       m_CheckBoxes.push_back(box);
     }
   }
 
   void SetVisible(bool vis)
   {
     foreach(QCheckBox * box, m_CheckBoxes)
     {
       box->setVisible(vis);
     }
   }
 
   BValueMap GetBValueSelctionMap()
   {
     BValueMap inputMap = m_Image->GetB_ValueMap();
     BValueMap outputMap;
 
     double val = 0;
 
     if(inputMap.find(0) == inputMap.end()){
       MITK_INFO << "QbrShellSelection: return empty BValueMap from GUI Selection";
       return outputMap;
     }else{
        outputMap[val] = inputMap[val];
        MITK_INFO << val;
     }
 
     foreach(QCheckBox * box, m_CheckBoxes)
     {
       if(box->isChecked()){
         val = box->text().toDouble();
         outputMap[val] = inputMap[val];
         MITK_INFO << val;
       }
     }
 
     return outputMap;
   }
 
   ~QbrShellSelection()
   {
     m_View->m_Controls->m_QBallSelectionBox->layout()->removeWidget(m_Label);
     delete m_Label;
 
     for(std::vector<QCheckBox *>::iterator it = m_CheckBoxes.begin() ; it!= m_CheckBoxes.end(); it++)
     {
       m_View->m_Controls->m_QBallSelectionBox->layout()->removeWidget((*it));
       delete (*it);
     }
     m_CheckBoxes.clear();
   }
 };
 
 using namespace berry;
 
 struct QbrSelListener : ISelectionListener
 {
 
   berryObjectMacro(QbrSelListener);
 
   QbrSelListener(QmitkQBallReconstructionView* view)
   {
     m_View = view;
   }
 
   void DoSelectionChanged(ISelection::ConstPointer selection)
   {
     // save current selection in member variable
     m_View->m_CurrentSelection = selection.Cast<const IStructuredSelection>();
 
     // do something with the selected items
     if(m_View->m_CurrentSelection)
     {
       bool foundDwiVolume = false;
       m_View->m_Controls->m_DiffusionImageLabel->setText("-");
 
       QString selected_images = "";
 
       mitk::DataStorage::SetOfObjects::Pointer set =
           mitk::DataStorage::SetOfObjects::New();
 
       int at = 0;
 
       // iterate selection
       for (IStructuredSelection::iterator i = m_View->m_CurrentSelection->Begin();
            i != m_View->m_CurrentSelection->End(); ++i)
       {
 
         // extract datatree node
         if (mitk::DataNodeObject::Pointer nodeObj = i->Cast<mitk::DataNodeObject>())
         {
           mitk::DataNode::Pointer node = nodeObj->GetDataNode();
           mitk::DiffusionImage<DiffusionPixelType>* diffusionImage;
           // only look at interesting types
           if(diffusionImage = dynamic_cast<mitk::DiffusionImage<DiffusionPixelType> * >(node->GetData()))
           {
             foundDwiVolume = true;
             selected_images += QString(node->GetName().c_str());
             if(i + 1 != m_View->m_CurrentSelection->End())
               selected_images += "\n";
             set->InsertElement(at++, node);
           }
         }
       }
       m_View->GenerateShellSelectionUI(set);
       m_View->m_Controls->m_DiffusionImageLabel->setText(selected_images);
       m_View->m_Controls->m_ButtonStandard->setEnabled(foundDwiVolume);
     }
   }
 
   void SelectionChanged(IWorkbenchPart::Pointer part, ISelection::ConstPointer selection)
   {
     // check, if selection comes from datamanager
     if (part)
     {
       QString partname(part->GetPartName().c_str());
       if(partname.compare("Datamanager")==0)
       {
 
         // apply selection
         DoSelectionChanged(selection);
 
       }
     }
   }
 
   QmitkQBallReconstructionView* m_View;
 };
 
 
 // --------------- QmitkQBallReconstructionView----------------- //
 
 
 QmitkQBallReconstructionView::QmitkQBallReconstructionView()
   : QmitkFunctionality(),
     m_Controls(NULL),
     m_MultiWidget(NULL)
 {
 }
 
 QmitkQBallReconstructionView::QmitkQBallReconstructionView(const QmitkQBallReconstructionView& other)
 {
   Q_UNUSED(other);
   throw std::runtime_error("Copy constructor not implemented");
 }
 
 QmitkQBallReconstructionView::~QmitkQBallReconstructionView()
 {
   this->GetSite()->GetWorkbenchWindow()->GetSelectionService()->RemovePostSelectionListener(/*"org.mitk.views.datamanager",*/ m_SelListener);
 }
 
 void QmitkQBallReconstructionView::CreateQtPartControl(QWidget *parent)
 {
   if (!m_Controls)
   {
     // create GUI widgets
     m_Controls = new Ui::QmitkQBallReconstructionViewControls;
     m_Controls->setupUi(parent);
     this->CreateConnections();
 
     QStringList items;
     items << "2" << "4" << "6" << "8" << "10" << "12";
     m_Controls->m_QBallReconstructionMaxLLevelComboBox->addItems(items);
     m_Controls->m_QBallReconstructionMaxLLevelComboBox->setCurrentIndex(1);
     MethodChoosen(m_Controls->m_QBallReconstructionMethodComboBox->currentIndex());
 
 
 #ifndef DIFFUSION_IMAGING_EXTENDED
     m_Controls->m_QBallReconstructionMethodComboBox->removeItem(3);
 #endif
 
     AdvancedCheckboxClicked();
   }
 
   m_SelListener = berry::ISelectionListener::Pointer(new QbrSelListener(this));
   this->GetSite()->GetWorkbenchWindow()->GetSelectionService()->AddPostSelectionListener(/*"org.mitk.views.datamanager",*/ m_SelListener);
   berry::ISelection::ConstPointer sel(
         this->GetSite()->GetWorkbenchWindow()->GetSelectionService()->GetSelection("org.mitk.views.datamanager"));
   m_CurrentSelection = sel.Cast<const IStructuredSelection>();
   m_SelListener.Cast<QbrSelListener>()->DoSelectionChanged(sel);
 }
 
 void QmitkQBallReconstructionView::StdMultiWidgetAvailable (QmitkStdMultiWidget &stdMultiWidget)
 {
   m_MultiWidget = &stdMultiWidget;
 }
 
 void QmitkQBallReconstructionView::StdMultiWidgetNotAvailable()
 {
   m_MultiWidget = NULL;
 }
 
 void QmitkQBallReconstructionView::CreateConnections()
 {
   if ( m_Controls )
   {
     connect( (QObject*)(m_Controls->m_ButtonStandard), SIGNAL(clicked()), this, SLOT(ReconstructStandard()) );
     connect( (QObject*)(m_Controls->m_AdvancedCheckbox), SIGNAL(clicked()), this, SLOT(AdvancedCheckboxClicked()) );
     connect( (QObject*)(m_Controls->m_QBallReconstructionMethodComboBox), SIGNAL(currentIndexChanged(int)), this, SLOT(MethodChoosen(int)) );
 
   }
 }
 
 void QmitkQBallReconstructionView::OnSelectionChanged( std::vector<mitk::DataNode*> nodes )
 {
 
 }
 
 void QmitkQBallReconstructionView::Activated()
 {
   QmitkFunctionality::Activated();
 
   berry::ISelection::ConstPointer sel(
         this->GetSite()->GetWorkbenchWindow()->GetSelectionService()->GetSelection("org.mitk.views.datamanager"));
   m_CurrentSelection = sel.Cast<const IStructuredSelection>();
   m_SelListener.Cast<QbrSelListener>()->DoSelectionChanged(sel);
 }
 
 void QmitkQBallReconstructionView::Deactivated()
 {
   QmitkFunctionality::Deactivated();
 }
 
 void QmitkQBallReconstructionView::ReconstructStandard()
 {
 
   int index = m_Controls->m_QBallReconstructionMethodComboBox->currentIndex();
 
 #ifndef DIFFUSION_IMAGING_EXTENDED
   if(index>=3)
   {
     index = index + 1;
   }
 #endif
 
   switch(index)
   {
   case 0:
   {
     // Numerical
     Reconstruct(0,0);
     break;
   }
   case 1:
   {
     // Standard
     Reconstruct(1,0);
     break;
   }
   case 2:
   {
     // Solid Angle
     Reconstruct(1,6);
     break;
   }
   case 3:
   {
     // Constrained Solid Angle
     Reconstruct(1,7);
     break;
   }
   case 4:
   {
     // ADC
     Reconstruct(1,4);
     break;
   }
   case 5:
   {
     // Raw Signal
     Reconstruct(1,5);
     break;
   }
   case 6:
   {
     // Q-Ball reconstruction
     Reconstruct(2,0);
     break;
   }
   }
 }
 
 void QmitkQBallReconstructionView::MethodChoosen(int method)
 {
 
 #ifndef DIFFUSION_IMAGING_EXTENDED
   if(method>=3)
   {
     method = method + 1;
   }
 #endif
 
   m_Controls->m_QBallSelectionBox->setHidden(true);
 
   switch(method)
   {
   case 0:
     m_Controls->m_Description->setText("Numerical recon. (Tuch2004)");
     break;
   case 1:
     m_Controls->m_Description->setText("Spherical harmonics recon. (Descoteaux2007)");
     break;
   case 2:
     m_Controls->m_Description->setText("SH recon. with solid angle consideration (Aganj2009)");
     break;
   case 3:
     m_Controls->m_Description->setText("SH solid angle with non-neg. constraint (Goh2009)");
     break;
   case 4:
     m_Controls->m_Description->setText("SH recon. of the plain ADC-profiles");
     break;
   case 5:
     m_Controls->m_Description->setText("SH recon. of the raw diffusion signal");
     break;
   case 6:
     m_Controls->m_Description->setText("SH Multi q-Ball recon. of the multi q-Ball diffusion signal");
     m_Controls->m_QBallSelectionBox->setHidden(false);
     break;
   }
 }
 
 
 
 void QmitkQBallReconstructionView::AdvancedCheckboxClicked()
 {
   bool check = m_Controls->
       m_AdvancedCheckbox->isChecked();
 
   m_Controls->m_QBallReconstructionMaxLLevelTextLabel_2->setVisible(check);
   m_Controls->m_QBallReconstructionMaxLLevelComboBox->setVisible(check);
   m_Controls->m_QBallReconstructionLambdaTextLabel_2->setVisible(check);
   m_Controls->m_QBallReconstructionLambdaLineEdit->setVisible(check);
 
   m_Controls->m_QBallReconstructionThresholdLabel_2->setVisible(check);
   m_Controls->m_QBallReconstructionThreasholdEdit->setVisible(check);
   m_Controls->m_OutputB0Image->setVisible(check);
   m_Controls->label_2->setVisible(check);
 
   //m_Controls->textLabel1_2->setVisible(check);
   //m_Controls->m_QBallReconstructionLambdaStepLineEdit->setVisible(check);
   //m_Controls->textLabel1_3->setVisible(check);
 
   m_Controls->frame_2->setVisible(check);
 }
 
 void QmitkQBallReconstructionView::Reconstruct(int method, int normalization)
 {
   if (m_CurrentSelection)
   {
     mitk::DataStorage::SetOfObjects::Pointer set =
         mitk::DataStorage::SetOfObjects::New();
 
     int at = 0;
     for (IStructuredSelection::iterator i = m_CurrentSelection->Begin();
          i != m_CurrentSelection->End();
          ++i)
     {
 
       if (mitk::DataNodeObject::Pointer nodeObj = i->Cast<mitk::DataNodeObject>())
       {
         mitk::DataNode::Pointer node = nodeObj->GetDataNode();
         if(QString("DiffusionImage").compare(node->GetData()->GetNameOfClass())==0)
         {
           set->InsertElement(at++, node);
         }
       }
     }
 
     if(method == 0)
     {
       NumericalQBallReconstruction(set, normalization);
     }
     else
     {
 #if BOOST_VERSION / 100000 > 0
 #if BOOST_VERSION / 100 % 1000 > 34
       if(method == 1)
       {
         AnalyticalQBallReconstruction(set, normalization);
       }
       if(method == 2)
       {
         MultiQBallReconstruction(set);
       }
 #else
       std::cout << "ERROR: Boost 1.35 minimum required" << std::endl;
       QMessageBox::warning(NULL,"ERROR","Boost 1.35 minimum required");
 #endif
 #else
       std::cout << "ERROR: Boost 1.35 minimum required" << std::endl;
       QMessageBox::warning(NULL,"ERROR","Boost 1.35 minimum required");
 #endif
     }
   }
 }
 
 void QmitkQBallReconstructionView::NumericalQBallReconstruction
 (mitk::DataStorage::SetOfObjects::Pointer inImages, int normalization)
 {
   try
   {
     itk::TimeProbe clock;
 
     int nrFiles = inImages->size();
     if (!nrFiles) return;
 
     QString status;
     mitk::ProgressBar::GetInstance()->AddStepsToDo(nrFiles);
 
     mitk::DataStorage::SetOfObjects::const_iterator itemiter( inImages->begin() );
     mitk::DataStorage::SetOfObjects::const_iterator itemiterend( inImages->end() );
 
     std::vector<mitk::DataNode::Pointer> nodes;
     while ( itemiter != itemiterend ) // for all items
     {
 
       mitk::DiffusionImage<DiffusionPixelType>* vols =
           static_cast<mitk::DiffusionImage<DiffusionPixelType>*>(
             (*itemiter)->GetData());
 
       std::string nodename;
       (*itemiter)->GetStringProperty("name", nodename);
       ++itemiter;
 
       // QBALL RECONSTRUCTION
       clock.Start();
       MBI_INFO << "QBall reconstruction ";
       mitk::StatusBar::GetInstance()->DisplayText(status.sprintf(
                                                     "QBall reconstruction for %s", nodename.c_str()).toAscii());
 
       typedef itk::DiffusionQballReconstructionImageFilter
           <DiffusionPixelType, DiffusionPixelType, TTensorPixelType, QBALL_ODFSIZE>
           QballReconstructionImageFilterType;
 
       QballReconstructionImageFilterType::Pointer filter =
           QballReconstructionImageFilterType::New();
       filter->SetGradientImage( vols->GetDirections(), vols->GetVectorImage() );
       filter->SetBValue(vols->GetB_Value());
       filter->SetThreshold( m_Controls->m_QBallReconstructionThreasholdEdit->text().toFloat() );
 
       switch(normalization)
       {
       case 0:
       {
         filter->SetNormalizationMethod(QballReconstructionImageFilterType::QBR_STANDARD);
         break;
       }
       case 1:
       {
         filter->SetNormalizationMethod(QballReconstructionImageFilterType::QBR_B_ZERO_B_VALUE);
         break;
       }
       case 2:
       {
         filter->SetNormalizationMethod(QballReconstructionImageFilterType::QBR_B_ZERO);
         break;
       }
       case 3:
       {
         filter->SetNormalizationMethod(QballReconstructionImageFilterType::QBR_NONE);
         break;
       }
       default:
       {
         filter->SetNormalizationMethod(QballReconstructionImageFilterType::QBR_STANDARD);
       }
       }
 
       filter->Update();
       clock.Stop();
       MBI_DEBUG << "took " << clock.GetMeanTime() << "s." ;
 
       // ODFs TO DATATREE
       mitk::QBallImage::Pointer image = mitk::QBallImage::New();
       image->InitializeByItk( filter->GetOutput() );
       //image->SetImportVolume( filter->GetOutput()->GetBufferPointer(), 0, 0, mitk::Image::ImportMemoryManagementType::ManageMemory );
       image->SetVolume( filter->GetOutput()->GetBufferPointer() );
       mitk::DataNode::Pointer node=mitk::DataNode::New();
       node->SetData( image );
       QString newname;
       newname = newname.append(nodename.c_str());
       newname = newname.append("_QN%1").arg(normalization);
       SetDefaultNodeProperties(node, newname.toStdString());
       nodes.push_back(node);
 
       // B-Zero TO DATATREE
       if(m_Controls->m_OutputB0Image->isChecked())
       {
         mitk::Image::Pointer image4 = mitk::Image::New();
         image4->InitializeByItk( filter->GetBZeroImage().GetPointer() );
         image4->SetVolume( filter->GetBZeroImage()->GetBufferPointer() );
         mitk::DataNode::Pointer node4=mitk::DataNode::New();
         node4->SetData( image4 );
         node4->SetProperty( "name", mitk::StringProperty::New(
                               QString(nodename.c_str()).append("_b0").toStdString()) );
         nodes.push_back(node4);
       }
       mitk::ProgressBar::GetInstance()->Progress();
 
     }
 
     std::vector<mitk::DataNode::Pointer>::iterator nodeIt;
     for(nodeIt = nodes.begin(); nodeIt != nodes.end(); ++nodeIt)
       GetDefaultDataStorage()->Add(*nodeIt);
 
     mitk::StatusBar::GetInstance()->DisplayText(status.sprintf("Finished Processing %d Files", nrFiles).toAscii());
     m_MultiWidget->RequestUpdate();
 
   }
   catch (itk::ExceptionObject &ex)
   {
     MBI_INFO << ex ;
     return ;
   }
 }
 
 void QmitkQBallReconstructionView::AnalyticalQBallReconstruction(
     mitk::DataStorage::SetOfObjects::Pointer inImages,
     int normalization)
 {
   try
   {
     itk::TimeProbe clock;
 
     int nrFiles = inImages->size();
     if (!nrFiles) return;
 
     std::vector<float> lambdas;
     float minLambda  = m_Controls->m_QBallReconstructionLambdaLineEdit->text().toFloat();
     lambdas.push_back(minLambda);
     int nLambdas = lambdas.size();
 
 
     QString status;
     mitk::ProgressBar::GetInstance()->AddStepsToDo(nrFiles*nLambdas);
 
     mitk::DataStorage::SetOfObjects::const_iterator itemiter( inImages->begin() );
     mitk::DataStorage::SetOfObjects::const_iterator itemiterend( inImages->end() );
 
     std::vector<mitk::DataNode::Pointer>* nodes
         = new std::vector<mitk::DataNode::Pointer>();
     while ( itemiter != itemiterend ) // for all items
     {
 
       mitk::DiffusionImage<DiffusionPixelType>* vols =
           static_cast<mitk::DiffusionImage<DiffusionPixelType>*>(
             (*itemiter)->GetData());
 
       std::string nodename;
       (*itemiter)->GetStringProperty("name",nodename);
       itemiter++;
 
       // QBALL RECONSTRUCTION
       clock.Start();
       MBI_INFO << "QBall reconstruction ";
       mitk::StatusBar::GetInstance()->DisplayText(status.sprintf(
                                                     "QBall reconstruction for %s", nodename.c_str()).toAscii());
 
       for(int i=0; i<nLambdas; i++)
       {
 
         float currentLambda = lambdas[i];
 
         switch(m_Controls->m_QBallReconstructionMaxLLevelComboBox->currentIndex())
         {
         case 0:
         {
           TemplatedAnalyticalQBallReconstruction<2>(vols, currentLambda, nodename, nodes, normalization);
           break;
         }
         case 1:
         {
           TemplatedAnalyticalQBallReconstruction<4>(vols, currentLambda, nodename, nodes, normalization);
           break;
         }
         case 2:
         {
           TemplatedAnalyticalQBallReconstruction<6>(vols, currentLambda, nodename, nodes, normalization);
           break;
         }
         case 3:
         {
           TemplatedAnalyticalQBallReconstruction<8>(vols, currentLambda, nodename, nodes, normalization);
           break;
         }
         case 4:
         {
           TemplatedAnalyticalQBallReconstruction<10>(vols, currentLambda, nodename, nodes, normalization);
           break;
         }
         case 5:
         {
           TemplatedAnalyticalQBallReconstruction<12>(vols, currentLambda, nodename, nodes, normalization);
           break;
         }
         }
 
         clock.Stop();
         MBI_DEBUG << "took " << clock.GetMeanTime() << "s." ;
         mitk::ProgressBar::GetInstance()->Progress();
 
       }
     }
 
     std::vector<mitk::DataNode::Pointer>::iterator nodeIt;
     for(nodeIt = nodes->begin(); nodeIt != nodes->end(); ++nodeIt)
       GetDefaultDataStorage()->Add(*nodeIt);
 
     m_MultiWidget->RequestUpdate();
 
     mitk::StatusBar::GetInstance()->DisplayText(status.sprintf("Finished Processing %d Files", nrFiles).toAscii());
 
   }
   catch (itk::ExceptionObject &ex)
   {
     MBI_INFO << ex ;
     return ;
   }
 }
 
 template<int L>
 void QmitkQBallReconstructionView::TemplatedAnalyticalQBallReconstruction(
     mitk::DiffusionImage<DiffusionPixelType>* vols, float lambda,
     std::string nodename, std::vector<mitk::DataNode::Pointer>* nodes,
     int normalization)
 {
   typedef itk::AnalyticalDiffusionQballReconstructionImageFilter
       <DiffusionPixelType,DiffusionPixelType,TTensorPixelType,L,QBALL_ODFSIZE> FilterType;
   typename FilterType::Pointer filter = FilterType::New();
   filter->SetGradientImage( vols->GetDirections(), vols->GetVectorImage() );
   filter->SetBValue(vols->GetB_Value());
   filter->SetThreshold( m_Controls->m_QBallReconstructionThreasholdEdit->text().toFloat() );
   filter->SetLambda(lambda);
 
   switch(normalization)
   {
   case 0:
   {
     filter->SetNormalizationMethod(FilterType::QBAR_STANDARD);
     break;
   }
   case 1:
   {
     filter->SetNormalizationMethod(FilterType::QBAR_B_ZERO_B_VALUE);
     break;
   }
   case 2:
   {
     filter->SetNormalizationMethod(FilterType::QBAR_B_ZERO);
     break;
   }
   case 3:
   {
     filter->SetNormalizationMethod(FilterType::QBAR_NONE);
     break;
   }
   case 4:
   {
     filter->SetNormalizationMethod(FilterType::QBAR_ADC_ONLY);
     break;
   }
   case 5:
   {
     filter->SetNormalizationMethod(FilterType::QBAR_RAW_SIGNAL);
     break;
   }
   case 6:
   {
     filter->SetNormalizationMethod(FilterType::QBAR_SOLID_ANGLE);
     break;
   }
   case 7:
   {
     filter->SetNormalizationMethod(FilterType::QBAR_NONNEG_SOLID_ANGLE);
     break;
   }
   default:
   {
     filter->SetNormalizationMethod(FilterType::QBAR_STANDARD);
   }
   }
 
   filter->Update();
 
   // ODFs TO DATATREE
   mitk::QBallImage::Pointer image = mitk::QBallImage::New();
   image->InitializeByItk( filter->GetOutput() );
   image->SetVolume( filter->GetOutput()->GetBufferPointer() );
   mitk::DataNode::Pointer node=mitk::DataNode::New();
   node->SetData( image );
   QString newname;
   newname = newname.append(nodename.c_str());
   newname = newname.append("_QA%1").arg(normalization);
   SetDefaultNodeProperties(node, newname.toStdString());
   nodes->push_back(node);
 
 
   //  mitk::Image::Pointer image5 = mitk::Image::New();
   //  image5->InitializeByItk( filter->GetODFSumImage().GetPointer() );
   //  image5->SetVolume( filter->GetODFSumImage()->GetBufferPointer() );
   //  mitk::DataNode::Pointer node5=mitk::DataNode::New();
   //  node5->SetData( image5 );
   //  node5->SetProperty( "name", mitk::StringProperty::New(
   //    QString(nodename.c_str()).append("_ODF").toStdString()) );
   //  nodes->push_back(node5);
 
   // B-Zero TO DATATREE
   if(m_Controls->m_OutputB0Image->isChecked())
   {
     mitk::Image::Pointer image4 = mitk::Image::New();
     image4->InitializeByItk( filter->GetBZeroImage().GetPointer() );
     image4->SetVolume( filter->GetBZeroImage()->GetBufferPointer() );
     mitk::DataNode::Pointer node4=mitk::DataNode::New();
     node4->SetData( image4 );
     node4->SetProperty( "name", mitk::StringProperty::New(
                           QString(nodename.c_str()).append("_b0").toStdString()) );
     nodes->push_back(node4);
   }
 
 }
 
 void QmitkQBallReconstructionView::MultiQBallReconstruction(
     mitk::DataStorage::SetOfObjects::Pointer inImages)
 {
   try
   {
     itk::TimeProbe clock;
 
     int nrFiles = inImages->size();
     if (!nrFiles) return;
 
     std::vector<float> lambdas;
     float minLambda  = m_Controls->m_QBallReconstructionLambdaLineEdit->text().toFloat();
     lambdas.push_back(minLambda);
     int nLambdas = lambdas.size();
 
 
     QString status;
     mitk::ProgressBar::GetInstance()->AddStepsToDo(nrFiles*nLambdas);
 
     mitk::DataStorage::SetOfObjects::const_iterator itemiter( inImages->begin() );
     mitk::DataStorage::SetOfObjects::const_iterator itemiterend( inImages->end() );
 
     std::vector<mitk::DataNode::Pointer>* nodes
         = new std::vector<mitk::DataNode::Pointer>();
     while ( itemiter != itemiterend ) // for all items
     {
 
       mitk::DiffusionImage<DiffusionPixelType>* vols =
           static_cast<mitk::DiffusionImage<DiffusionPixelType>*>(
             (*itemiter)->GetData());
 
       std::string nodename;
       (*itemiter)->GetStringProperty("name",nodename);
       itemiter++;
 
       // QBALL RECONSTRUCTION
       clock.Start();
       MBI_INFO << "QBall reconstruction ";
       mitk::StatusBar::GetInstance()->DisplayText(status.sprintf(
                                                     "QBall reconstruction for %s", nodename.c_str()).toAscii());
 
       for(int i=0; i<nLambdas; i++)
       {
 
         float currentLambda = lambdas[i];
 
         switch(m_Controls->m_QBallReconstructionMaxLLevelComboBox->currentIndex())
         {
         case 0:
         {
           TemplatedMultiQBallReconstruction<2>(vols, currentLambda, nodename, nodes);
           break;
         }
         case 1:
         {
           TemplatedMultiQBallReconstruction<4>(vols, currentLambda, nodename, nodes);
           break;
         }
         case 2:
         {
           TemplatedMultiQBallReconstruction<6>(vols, currentLambda, nodename, nodes);
           break;
         }
         case 3:
         {
           TemplatedMultiQBallReconstruction<8>(vols, currentLambda, nodename, nodes);
           break;
         }
         case 4:
         {
           TemplatedMultiQBallReconstruction<10>(vols, currentLambda, nodename, nodes);
           break;
         }
         case 5:
         {
           TemplatedMultiQBallReconstruction<12>(vols, currentLambda, nodename, nodes);
           break;
         }
         }
 
         clock.Stop();
         MBI_DEBUG << "took " << clock.GetMeanTime() << "s." ;
         mitk::ProgressBar::GetInstance()->Progress();
 
       }
     }
 
     std::vector<mitk::DataNode::Pointer>::iterator nodeIt;
     for(nodeIt = nodes->begin(); nodeIt != nodes->end(); ++nodeIt)
       GetDefaultDataStorage()->Add(*nodeIt);
 
     m_MultiWidget->RequestUpdate();
 
     mitk::StatusBar::GetInstance()->DisplayText(status.sprintf("Finished Processing %d Files", nrFiles).toAscii());
 
   }
   catch (itk::ExceptionObject &ex)
   {
     MBI_INFO << ex ;
     return ;
   }
 }
 
 template<int L>
 void QmitkQBallReconstructionView::TemplatedMultiQBallReconstruction(
     mitk::DiffusionImage<DiffusionPixelType>* vols, float lambda,
     std::string nodename, std::vector<mitk::DataNode::Pointer>* nodes)
 {
   typedef itk::DiffusionMultiShellQballReconstructionImageFilter
       <DiffusionPixelType,DiffusionPixelType,TTensorPixelType,L,QBALL_ODFSIZE> FilterType;
   typename FilterType::Pointer filter = FilterType::New();
 
   filter->SetBValueMap(m_ShellSelectorMap[nodename]->GetBValueSelctionMap());
   filter->SetGradientImage( vols->GetDirections(), vols->GetVectorImage(), vols->GetB_Value() );
 
   //filter->SetBValue(vols->GetB_Value()); 
   filter->SetThreshold( m_Controls->m_QBallReconstructionThreasholdEdit->text().toFloat() );
   filter->SetLambda(lambda);
 
 
   filter->Update();
 
   // ODFs TO DATATREE
   mitk::QBallImage::Pointer image = mitk::QBallImage::New();
   image->InitializeByItk( filter->GetOutput() );
   image->SetVolume( filter->GetOutput()->GetBufferPointer() );
   mitk::DataNode::Pointer node=mitk::DataNode::New();
   node->SetData( image );
   QString newname;
   newname = newname.append(nodename.c_str());
   newname = newname.append("_QAMultiShell");
   SetDefaultNodeProperties(node, newname.toStdString());
   nodes->push_back(node);
 
   // B-Zero TO DATATREE
   if(m_Controls->m_OutputB0Image->isChecked())
   {
     mitk::Image::Pointer image4 = mitk::Image::New();
     image4->InitializeByItk( filter->GetBZeroImage().GetPointer() );
     image4->SetVolume( filter->GetBZeroImage()->GetBufferPointer() );
     mitk::DataNode::Pointer node4=mitk::DataNode::New();
     node4->SetData( image4 );
     node4->SetProperty( "name", mitk::StringProperty::New(
                           QString(nodename.c_str()).append("_b0").toStdString()) );
     nodes->push_back(node4);
   }
 
 
-}
-
-mitk::DiffusionImage<DiffusionPixelType>::BValueMap GenerateBValueMapFromGui(std::string nodename)
-{
-
 }
 
 void QmitkQBallReconstructionView::SetDefaultNodeProperties(mitk::DataNode::Pointer node, std::string name)
 {
   node->SetProperty( "ShowMaxNumber", mitk::IntProperty::New( 500 ) );
   node->SetProperty( "Scaling", mitk::FloatProperty::New( 1.0 ) );
   node->SetProperty( "Normalization", mitk::OdfNormalizationMethodProperty::New());
   node->SetProperty( "ScaleBy", mitk::OdfScaleByProperty::New());
   node->SetProperty( "IndexParam1", mitk::FloatProperty::New(2));
   node->SetProperty( "IndexParam2", mitk::FloatProperty::New(1));
   node->SetProperty( "visible", mitk::BoolProperty::New( true ) );
   node->SetProperty( "VisibleOdfs", mitk::BoolProperty::New( false ) );
   node->SetProperty ("layer", mitk::IntProperty::New(100));
   node->SetProperty( "DoRefresh", mitk::BoolProperty::New( true ) );
   //node->SetProperty( "opacity", mitk::FloatProperty::New(1.0f) );
 
   node->SetProperty( "name", mitk::StringProperty::New(name) );
 
 }
 
 
 //node->SetProperty( "volumerendering", mitk::BoolProperty::New( false ) );
 //node->SetProperty( "use color", mitk::BoolProperty::New( true ) );
 //node->SetProperty( "texture interpolation", mitk::BoolProperty::New( true ) );
 //node->SetProperty( "reslice interpolation", mitk::VtkResliceInterpolationProperty::New() );
 //node->SetProperty( "layer", mitk::IntProperty::New(0));
 //node->SetProperty( "in plane resample extent by geometry", mitk::BoolProperty::New( false ) );
 //node->SetOpacity(1.0f);
 //node->SetColor(1.0,1.0,1.0);
 //node->SetVisibility(true);
 //node->SetProperty( "IsQBallVolume", mitk::BoolProperty::New( true ) );
 
 //mitk::LevelWindowProperty::Pointer levWinProp = mitk::LevelWindowProperty::New();
 //mitk::LevelWindow levelwindow;
 ////  levelwindow.SetAuto( image );
 //levWinProp->SetLevelWindow( levelwindow );
 //node->GetPropertyList()->SetPropertx( "levelwindow", levWinProp );
 
 //// add a default rainbow lookup table for color mapping
 //if(!node->GetProperty("LookupTable"))
 //{
 //  mitk::LookupTable::Pointer mitkLut = mitk::LookupTable::New();
 //  vtkLookupTable* vtkLut = mitkLut->GetVtkLookupTable();
 //  vtkLut->SetHueRange(0.6667, 0.0);
 //  vtkLut->SetTableRange(0.0, 20.0);
 //  vtkLut->Build();
 //  mitk::LookupTableProperty::Pointer mitkLutProp = mitk::LookupTableProperty::New();
 //  mitkLutProp->SetLookupTable(mitkLut);
 //  node->SetProperty( "LookupTable", mitkLutProp );
 //}
 //if(!node->GetProperty("binary"))
 //  node->SetProperty( "binary", mitk::BoolProperty::New( false ) );
 
 //// add a default transfer function
 //mitk::TransferFunction::Pointer tf = mitk::TransferFunction::New();
 //node->SetProperty ( "TransferFunction", mitk::TransferFunctionProperty::New ( tf.GetPointer() ) );
 
 //// set foldername as string property
 //mitk::StringProperty::Pointer nameProp = mitk::StringProperty::New( name );
 //node->SetProperty( "name", nameProp );
 
 
 void QmitkQBallReconstructionView::GenerateShellSelectionUI(mitk::DataStorage::SetOfObjects::Pointer set)
 {
 
   std::map<std::string , QbrShellSelection * > tempMap;
 
   const mitk::DataStorage::SetOfObjects::iterator setEnd( set->end() );
   mitk::DataStorage::SetOfObjects::iterator NodeIt( set->begin() );
   while(NodeIt != setEnd)
   {
     //mitk::DiffusionImage<DiffusionPixelType>* vols = static_cast<mitk::DiffusionImage<DiffusionPixelType>*>((*NodeIt)->GetData());
 
     std::string nodename;
     (*NodeIt)->GetStringProperty("name",nodename);
 
     if(m_ShellSelectorMap.find(nodename) != m_ShellSelectorMap.end())
     {
       tempMap[nodename] = m_ShellSelectorMap[nodename];
       m_ShellSelectorMap.erase(nodename);
     }else
     {
       tempMap[nodename] = new QbrShellSelection(this, (*NodeIt) );
       tempMap[nodename]->SetVisible(true);
     }
 
     NodeIt++;
   }
 
   for(std::map<std::string , QbrShellSelection * >::iterator it = m_ShellSelectorMap.begin(); it != m_ShellSelectorMap.end();it ++)
   {
     delete it->second;
   }
   m_ShellSelectorMap.clear();
   m_ShellSelectorMap = tempMap;
 }