diff --git a/Modules/PhotoacousticsAlgorithms/include/mitkCropImageFilter.h b/Modules/PhotoacousticsAlgorithms/include/mitkCropImageFilter.h
index 3b052dacb4..6b56156854 100644
--- a/Modules/PhotoacousticsAlgorithms/include/mitkCropImageFilter.h
+++ b/Modules/PhotoacousticsAlgorithms/include/mitkCropImageFilter.h
@@ -1,44 +1,68 @@
 /*===================================================================
 
 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_CROP_IMAGE_FILTER
 #define MITK_CROP_IMAGE_FILTER
 
 #include "mitkImageToImageFilter.h"
+#include "itkMacro.h"
 
 namespace mitk {
   /*!
   * \brief Class implementing an mitk::ImageToImageFilter for casting any mitk image to a float image
   */
 
   class CropImageFilter : public ImageToImageFilter
   {
   public:
     mitkClassMacro(CropImageFilter, ImageToImageFilter);
 
     itkFactorylessNewMacro(Self);
     itkCloneMacro(Self);
 
+    itkGetMacro(XPixelsCropStart, unsigned int);
+    itkSetMacro(XPixelsCropStart, unsigned int);
+    itkGetMacro(YPixelsCropStart, unsigned int);
+    itkSetMacro(YPixelsCropStart, unsigned int);
+    itkGetMacro(ZPixelsCropStart, unsigned int);
+    itkSetMacro(ZPixelsCropStart, unsigned int);
+
+    itkGetMacro(XPixelsCropEnd, unsigned int);
+    itkSetMacro(XPixelsCropEnd, unsigned int);
+    itkGetMacro(YPixelsCropEnd, unsigned int);
+    itkSetMacro(YPixelsCropEnd, unsigned int);
+    itkGetMacro(ZPixelsCropEnd, unsigned int);
+    itkSetMacro(ZPixelsCropEnd, unsigned int);
+
   protected:
     CropImageFilter();
 
     ~CropImageFilter() override;
 
     void GenerateData() override;
+
+    void SanityCheckPreconditions();
+
+    unsigned int m_XPixelsCropStart;
+    unsigned int m_XPixelsCropEnd;
+    unsigned int m_YPixelsCropStart;
+    unsigned int m_YPixelsCropEnd;
+    unsigned int m_ZPixelsCropStart;
+    unsigned int m_ZPixelsCropEnd;
   };
 } // namespace mitk
 
 #endif //MITK_CROP_IMAGE_FILTER
diff --git a/Modules/PhotoacousticsAlgorithms/source/filters/mitkCastToFloatImageFilter.cpp b/Modules/PhotoacousticsAlgorithms/source/filters/mitkCastToFloatImageFilter.cpp
index a03e9812e7..b8d6e8e995 100644
--- a/Modules/PhotoacousticsAlgorithms/source/filters/mitkCastToFloatImageFilter.cpp
+++ b/Modules/PhotoacousticsAlgorithms/source/filters/mitkCastToFloatImageFilter.cpp
@@ -1,92 +1,91 @@
 /*===================================================================
 mitkCastToFloatImageFilter
 The Medical Imaging Interaction Toolkit (MITK)
 
 Copyright (c) German Cancer Research Center,
 Division of Medical and Biological Informatics.
 All rights reserved.
 
 This software is distributed WITHOUT ANY WARRANTY; without
 even the implied warranty of MERCHANTABILITY or FITNESS FOR
 A PARTICULAR PURPOSE.
 
 See LICENSE.txt or http://www.mitk.org for details.
 
 ===================================================================*/
 
 #include "mitkCastToFloatImageFilter.h"
 #include "mitkImageReadAccessor.h"
 #include "mitkImageWriteAccessor.h"
 
 mitk::CastToFloatImageFilter::CastToFloatImageFilter()
 {
   MITK_INFO << "Instantiating CastToFloatImageFilter...";
   SetNumberOfIndexedInputs(1);
   SetNumberOfIndexedOutputs(1);
   MITK_INFO << "Instantiating CastToFloatImageFilter...[Done]";
 }
 
 mitk::CastToFloatImageFilter::~CastToFloatImageFilter()
 {
   MITK_INFO << "Destructed CastToFloatImageFilter.";
 }
 
 template<class TPixelType>
 float* CastData(const void* inputArray, unsigned long length)
 {
   float* outputArray = new float[length];
   for (unsigned long i = 0; i < length; ++i)
   {
     outputArray[i] = (float)((TPixelType*)inputArray)[i];
   }
   return outputArray;
 }
 
 void mitk::CastToFloatImageFilter::GenerateData()
 {
   mitk::Image::Pointer inputImage = GetInput();
   mitk::Image::Pointer outputImage = GetOutput();
 
   std::string type = inputImage->GetPixelType().GetTypeAsString();
 
   if (type == "scalar (float)" || type == " (float)")
   {
     outputImage->Initialize(mitk::MakeScalarPixelType<float>(), inputImage->GetDimension(), inputImage->GetDimensions());
     outputImage->SetSpacing(inputImage->GetGeometry()->GetSpacing());
     outputImage->SetImportVolume(mitk::ImageWriteAccessor(inputImage).GetData(), 0, 0, mitk::Image::ImportMemoryManagementType::RtlCopyMemory);
     MITK_INFO << "Input is already float type. Nothing to do here.";
     return;
   }
   if (outputImage.IsNull())
   {
     outputImage = mitk::Image::New();
   }
 
   unsigned long length = 1;
   for (unsigned int i = 0, limit = inputImage->GetDimension(); i < limit; ++i)
     length *= inputImage->GetDimensions()[i];
 
   float* outputData;
 
   mitk::ImageReadAccessor readAccess(inputImage);
 
   if (type == "scalar (short)" || type == " (short)")
     outputData = CastData<short>(readAccess.GetData(), length);
   else if (type == "scalar (unsigned short)" || type == " (unsigned short)" || type == " (unsigned_short)" || type == "scalar (unsigned_short)")
     outputData = CastData<unsigned short>(readAccess.GetData(), length);
   else if (type == "scalar (int)" || type == " (int)")
     outputData = CastData<int>(readAccess.GetData(), length);
   else if (type == "scalar (unsigned int)" || type == " (unsigned int)" || type == " (unsigned_int)" || type == "scalar (unsigned_int)")
     outputData = CastData<unsigned int>(readAccess.GetData(), length);
   else if (type == "scalar (double)" || type == " (double)")
     outputData = CastData<double>(readAccess.GetData(), length);
   else if (type == "scalar (long)" || type == " (long)")
     outputData = CastData<long>(readAccess.GetData(), length);
   else
     mitkThrow() << "The given image has a datatype that is not yet supported. Given datatype: " << type;
 
   outputImage->Initialize(mitk::MakeScalarPixelType<float>(), inputImage->GetDimension(), inputImage->GetDimensions());
   outputImage->SetSpacing(inputImage->GetGeometry()->GetSpacing());
   outputImage->SetImportVolume(outputData, 0, 0, mitk::Image::ImportMemoryManagementType::ManageMemory);
-  //delete[] outputData;
 }
diff --git a/Modules/PhotoacousticsAlgorithms/source/filters/mitkCropImageFilter.cpp b/Modules/PhotoacousticsAlgorithms/source/filters/mitkCropImageFilter.cpp
index 0e46c8d494..5ab767a9bd 100644
--- a/Modules/PhotoacousticsAlgorithms/source/filters/mitkCropImageFilter.cpp
+++ b/Modules/PhotoacousticsAlgorithms/source/filters/mitkCropImageFilter.cpp
@@ -1,34 +1,111 @@
 /*===================================================================
 mitkCropImageFilter
 The Medical Imaging Interaction Toolkit (MITK)
 
 Copyright (c) German Cancer Research Center,
 Division of Medical and Biological Informatics.
 All rights reserved.
 
 This software is distributed WITHOUT ANY WARRANTY; without
 even the implied warranty of MERCHANTABILITY or FITNESS FOR
 A PARTICULAR PURPOSE.
 
 See LICENSE.txt or http://www.mitk.org for details.
 
 ===================================================================*/
 
 #include "mitkCropImageFilter.h"
+#include <mitkImageReadAccessor.h>
+#include <mitkImageWriteAccessor.h>
 
-mitk::CropImageFilter::CropImageFilter()
+mitk::CropImageFilter::CropImageFilter() :
+  m_XPixelsCropEnd(0),
+  m_YPixelsCropEnd(0),
+  m_ZPixelsCropEnd(0),
+  m_XPixelsCropStart(0),
+  m_YPixelsCropStart(0),
+  m_ZPixelsCropStart(0)
 {
   MITK_INFO << "Instantiating CropImageFilter...";
   SetNumberOfIndexedInputs(1);
   SetNumberOfIndexedOutputs(1);
   MITK_INFO << "Instantiating CropImageFilter...[Done]";
 }
 
 mitk::CropImageFilter::~CropImageFilter()
 {
   MITK_INFO << "Destructed CastToFloatImageFilter.";
 }
 
+void mitk::CropImageFilter::SanityCheckPreconditions()
+{
+  mitk::Image::Pointer inputImage = GetInput();
+
+  std::string type = inputImage->GetPixelType().GetTypeAsString();
+  if (!(type == "scalar (float)" || type == " (float)"))
+  {
+    mitkThrow() << "This filter can currently only handle float type images.";
+  }
+
+  if (m_XPixelsCropStart + m_XPixelsCropEnd >= inputImage->GetDimension(0))
+    mitkThrow() << "X Crop area too large for selected input image";
+  if (m_YPixelsCropStart + m_YPixelsCropEnd >= inputImage->GetDimension(1))
+    mitkThrow() << "Y Crop area too large for selected input image";
+  if (inputImage->GetDimension() == 3)
+  {
+    if (m_ZPixelsCropStart + m_ZPixelsCropEnd >= inputImage->GetDimension(2))
+    {
+      mitkThrow() << "Z Crop area too large for selected input image";
+    }
+  }
+  else
+  {
+    if (m_ZPixelsCropStart + m_ZPixelsCropEnd > 0)
+    {
+      mitkThrow() << "Z Crop area too large for selected input image";
+    }
+  }
+}
+
 void mitk::CropImageFilter::GenerateData()
 {
+  mitk::Image::Pointer inputImage = GetInput();
+  mitk::Image::Pointer outputImage = GetOutput();
+
+  SanityCheckPreconditions();
+  unsigned int* outputDim;
+  unsigned int* inputDim = inputImage->GetDimensions();
+
+  if (inputImage->GetDimension() == 2)
+    outputDim = new unsigned int[2]{ inputImage->GetDimension(0) - m_XPixelsCropStart - m_XPixelsCropEnd,
+    inputImage->GetDimension(1) - m_YPixelsCropStart - m_YPixelsCropEnd };
+  else
+    outputDim = new unsigned int[3]{ inputImage->GetDimension(0) - m_XPixelsCropStart - m_XPixelsCropEnd,
+    inputImage->GetDimension(1) - m_YPixelsCropStart - m_YPixelsCropEnd,
+    inputImage->GetDimension(2) - m_ZPixelsCropStart - m_ZPixelsCropEnd };
+
+  outputImage->Initialize(mitk::MakeScalarPixelType<float>(), inputImage->GetDimension(), outputDim);
+  outputImage->SetSpacing(inputImage->GetGeometry()->GetSpacing());
+
+  ImageReadAccessor accR(inputImage);
+  const float* inputData = (const float*)(accR.GetData());
+
+  ImageWriteAccessor accW(outputImage);
+  float* outputData = (float*)(accW.GetData());
+
+  unsigned int zLength = inputImage->GetDimension() == 3 ? outputDim[2] : 0;
+
+  for (unsigned int sl = 0; sl < zLength; ++sl)
+  {
+    for (unsigned int l = 0; l < outputDim[0]; ++l)
+    {
+      for (unsigned int s = 0; s < outputDim[1]; ++s)
+      {
+        outputData[l + s*outputDim[0] + sl*outputDim[0] * outputDim[1]] =
+          inputData[(l + m_XPixelsCropStart) + (s + m_YPixelsCropStart)*inputDim[0] +
+          (sl + m_ZPixelsCropStart)*inputDim[0] * inputDim[1]];
+      }
+    }
+  }
+  delete[] outputDim;
 }
diff --git a/Modules/PhotoacousticsAlgorithms/source/utils/mitkPhotoacousticFilterService.cpp b/Modules/PhotoacousticsAlgorithms/source/utils/mitkPhotoacousticFilterService.cpp
index 652c2aedb6..e519762011 100644
--- a/Modules/PhotoacousticsAlgorithms/source/utils/mitkPhotoacousticFilterService.cpp
+++ b/Modules/PhotoacousticsAlgorithms/source/utils/mitkPhotoacousticFilterService.cpp
@@ -1,502 +1,442 @@
 /*===================================================================
 
 The Medical Imaging Interaction Toolkit (MITK)
 
 Copyright (c) German Cancer Research Center,
 Division of Medical and Biological Informatics.
 All rights reserved.
 
 This software is distributed WITHOUT ANY WARRANTY; without
 even the implied warranty of MERCHANTABILITY or FITNESS FOR
 A PARTICULAR PURPOSE.
 
 See LICENSE.txt or http://www.mitk.org for details.
 
 ===================================================================*/
 
 #include "mitkPhotoacousticFilterService.h"
 #include "../ITKFilter/ITKUltrasound/itkBModeImageFilter.h"
 #include "../ITKFilter/itkPhotoacousticBModeImageFilter.h"
 #include "mitkImageCast.h"
 #include "mitkITKImageImport.h"
 #include "mitkBeamformingFilter.h"
 #include <chrono>
 #include <mitkIOUtil.h>
-#include <mitkAutoCropImageFilter.h>
+#include <mitkCropImageFilter.h>
 #include "./OpenCLFilter/mitkPhotoacousticBModeFilter.h"
 #include "mitkConvert2Dto3DImageFilter.h"
+#include <mitkCastToFloatImageFilter.h>
 
 // itk dependencies
 #include "itkImage.h"
 #include "itkResampleImageFilter.h"
 #include "itkCastImageFilter.h"
 #include "itkCropImageFilter.h"
 #include "itkRescaleIntensityImageFilter.h"
 #include "itkIntensityWindowingImageFilter.h"
 #include <itkIndex.h>
 #include "itkMultiplyImageFilter.h"
 #include "itkBSplineInterpolateImageFunction.h"
 #include <mitkImageToItk.h>
 
 // needed itk image filters
 #include "mitkITKImageImport.h"
 #include "itkFFTShiftImageFilter.h"
 #include "itkMultiplyImageFilter.h"
 #include "itkComplexToModulusImageFilter.h"
 #include <itkAddImageFilter.h>
 #include "../ITKFilter/ITKUltrasound/itkFFT1DComplexConjugateToRealImageFilter.h"
 #include "../ITKFilter/ITKUltrasound/itkFFT1DRealToComplexConjugateImageFilter.h"
 
 mitk::PhotoacousticFilterService::PhotoacousticFilterService()
 {
   MITK_INFO << "[PhotoacousticFilterService] created filter service";
 }
 
 mitk::PhotoacousticFilterService::~PhotoacousticFilterService()
 {
   MITK_INFO << "[PhotoacousticFilterService] destructed filter service";
 }
 
 mitk::Image::Pointer mitk::PhotoacousticFilterService::ApplyBmodeFilter(mitk::Image::Pointer inputImage, BModeMethod method, bool UseGPU, bool UseLogFilter, float resampleSpacing)
 {
   // the image needs to be of floating point type for the envelope filter to work; the casting is done automatically by the CastToItkImage
   typedef itk::Image< float, 3 > itkFloatImageType;
   typedef itk::IdentityTransform<double, 3> TransformType;
 
   if (method == BModeMethod::Abs)
   {
     mitk::Image::Pointer input;
     mitk::Image::Pointer out;
     if (inputImage->GetPixelType().GetTypeAsString() == "scalar (float)" || inputImage->GetPixelType().GetTypeAsString() == " (float)")
       input = inputImage;
     else
-      input = ApplyCropping(inputImage, 0, 0, 0, 0, 0, inputImage->GetDimension(2) - 1);
+      input = ApplyCropping(inputImage, 0, 0, 0, 0, 0, 0);
 
     if (!UseGPU)
     {
       PhotoacousticBModeFilter::Pointer filter = PhotoacousticBModeFilter::New();
       filter->SetParameters(UseLogFilter);
       filter->SetInput(input);
       filter->Update();
 
       out = filter->GetOutput();
 
       if (resampleSpacing == 0)
         return out;
     }
 #ifdef PHOTOACOUSTICS_USE_GPU
     else
     {
       PhotoacousticOCLBModeFilter::Pointer filter = PhotoacousticOCLBModeFilter::New();
       filter->SetParameters(UseLogFilter);
       filter->SetInput(input);
       filter->Update();
 
       out = filter->GetOutput();
 
       if (resampleSpacing == 0)
         return out;
     }
 #endif
 
     typedef itk::ResampleImageFilter < itkFloatImageType, itkFloatImageType > ResampleImageFilter;
     ResampleImageFilter::Pointer resampleImageFilter = ResampleImageFilter::New();
 
     itkFloatImageType::Pointer itkImage;
     mitk::CastToItkImage(out, itkImage);
     itkFloatImageType::SpacingType outputSpacing;
     itkFloatImageType::SizeType inputSize = itkImage->GetLargestPossibleRegion().GetSize();
     itkFloatImageType::SizeType outputSize = inputSize;
 
     outputSpacing[0] = itkImage->GetSpacing()[0];
     outputSpacing[1] = resampleSpacing;
     outputSpacing[2] = itkImage->GetSpacing()[2];
 
     outputSize[1] = inputSize[1] * itkImage->GetSpacing()[1] / outputSpacing[1];
 
     typedef itk::IdentityTransform<double, 3> TransformType;
     resampleImageFilter->SetInput(itkImage);
     resampleImageFilter->SetSize(outputSize);
     resampleImageFilter->SetOutputSpacing(outputSpacing);
     resampleImageFilter->SetTransform(TransformType::New());
 
     resampleImageFilter->UpdateLargestPossibleRegion();
     return mitk::GrabItkImageMemory(resampleImageFilter->GetOutput());
   }
   else if (method == BModeMethod::EnvelopeDetection)
   {
     typedef itk::BModeImageFilter < itkFloatImageType, itkFloatImageType > BModeFilterType;
     BModeFilterType::Pointer bModeFilter = BModeFilterType::New();  // LogFilter
 
     typedef itk::PhotoacousticBModeImageFilter < itkFloatImageType, itkFloatImageType > PhotoacousticBModeImageFilter;
     PhotoacousticBModeImageFilter::Pointer photoacousticBModeFilter = PhotoacousticBModeImageFilter::New(); // No LogFilter
 
     typedef itk::ResampleImageFilter < itkFloatImageType, itkFloatImageType > ResampleImageFilter;
     ResampleImageFilter::Pointer resampleImageFilter = ResampleImageFilter::New();
 
     itkFloatImageType::Pointer itkImage;
 
     mitk::CastToItkImage(inputImage, itkImage);
 
     itkFloatImageType::Pointer bmode;
 
     if (UseLogFilter)
     {
       bModeFilter->SetInput(itkImage);
       bModeFilter->SetDirection(1);
       bmode = bModeFilter->GetOutput();
     }
     else
     {
       photoacousticBModeFilter->SetInput(itkImage);
       photoacousticBModeFilter->SetDirection(1);
       bmode = photoacousticBModeFilter->GetOutput();
     }
 
     // resampleSpacing == 0 means: do no resampling
     if (resampleSpacing == 0)
     {
       return mitk::GrabItkImageMemory(bmode);
     }
 
     itkFloatImageType::SpacingType outputSpacing;
     itkFloatImageType::SizeType inputSize = itkImage->GetLargestPossibleRegion().GetSize();
     itkFloatImageType::SizeType outputSize = inputSize;
 
     outputSpacing[0] = itkImage->GetSpacing()[0];
     outputSpacing[1] = resampleSpacing;
     outputSpacing[2] = itkImage->GetSpacing()[2];
 
     outputSize[1] = inputSize[1] * itkImage->GetSpacing()[1] / outputSpacing[1];
 
     resampleImageFilter->SetInput(bmode);
     resampleImageFilter->SetSize(outputSize);
     resampleImageFilter->SetOutputSpacing(outputSpacing);
     resampleImageFilter->SetTransform(TransformType::New());
 
     resampleImageFilter->UpdateLargestPossibleRegion();
     return mitk::GrabItkImageMemory(resampleImageFilter->GetOutput());
   }
   return nullptr;
 }
 
 mitk::Image::Pointer mitk::PhotoacousticFilterService::ApplyResampling(mitk::Image::Pointer inputImage, unsigned int outputSize[2])
 {
   typedef itk::Image< float, 3 > itkFloatImageType;
 
   typedef itk::ResampleImageFilter < itkFloatImageType, itkFloatImageType > ResampleImageFilter;
   ResampleImageFilter::Pointer resampleImageFilter = ResampleImageFilter::New();
   typedef itk::LinearInterpolateImageFunction<itkFloatImageType, double> T_Interpolator;
   itkFloatImageType::Pointer itkImage;
 
   mitk::CastToItkImage(inputImage, itkImage);
 
   itkFloatImageType::SpacingType outputSpacingItk;
   itkFloatImageType::SizeType inputSizeItk = itkImage->GetLargestPossibleRegion().GetSize();
   itkFloatImageType::SizeType outputSizeItk = inputSizeItk;
 
   outputSizeItk[0] = outputSize[0];
   outputSizeItk[1] = outputSize[1];
   outputSizeItk[2] = inputSizeItk[2];
 
   outputSpacingItk[0] = itkImage->GetSpacing()[0] * (static_cast<double>(inputSizeItk[0]) / static_cast<double>(outputSizeItk[0]));
   outputSpacingItk[1] = itkImage->GetSpacing()[1] * (static_cast<double>(inputSizeItk[1]) / static_cast<double>(outputSizeItk[1]));
   outputSpacingItk[2] = itkImage->GetSpacing()[2];
 
   typedef itk::IdentityTransform<double, 3> TransformType;
   T_Interpolator::Pointer _pInterpolator = T_Interpolator::New();
   resampleImageFilter->SetInput(itkImage);
   resampleImageFilter->SetSize(outputSizeItk);
   resampleImageFilter->SetOutputSpacing(outputSpacingItk);
   resampleImageFilter->SetTransform(TransformType::New());
   resampleImageFilter->SetInterpolator(_pInterpolator);
 
   resampleImageFilter->UpdateLargestPossibleRegion();
   return mitk::GrabItkImageMemory(resampleImageFilter->GetOutput());
 }
 
-mitk::Image::Pointer mitk::PhotoacousticFilterService::ApplyCropping(mitk::Image::Pointer inputImage, int above, int below, int right, int left, int minSlice, int maxSlice)
+mitk::Image::Pointer mitk::PhotoacousticFilterService::ApplyCropping(mitk::Image::Pointer inputImage,
+  int above, int below,
+  int right, int left,
+  int zStart, int zEnd)
 {
-  unsigned int inputDim[3] = { inputImage->GetDimension(0), inputImage->GetDimension(1), inputImage->GetDimension(2) };
-  unsigned int outputDim[3] = { inputImage->GetDimension(0) - left - right, inputImage->GetDimension(1) - (unsigned int)above - (unsigned int)below, (unsigned int)maxSlice - (unsigned int)minSlice + 1 };
-
-  void* inputData;
-  float* outputData = new float[outputDim[0] * outputDim[1] * outputDim[2]];
-
-  ImageReadAccessor acc(inputImage);
-  inputData = const_cast<void*>(acc.GetData());
-
-  // convert the data to float by default
-  // as of now only float, short, double are used at all.
-  if (inputImage->GetPixelType().GetTypeAsString() == "scalar (float)" || inputImage->GetPixelType().GetTypeAsString() == " (float)")
-  {
-    // copy the data into the cropped image
-    for (unsigned short sl = 0; sl < outputDim[2]; ++sl)
-    {
-      for (unsigned short l = 0; l < outputDim[0]; ++l)
-      {
-        for (unsigned short s = 0; s < outputDim[1]; ++s)
-        {
-          outputData[l + s*(unsigned short)outputDim[0] + sl*outputDim[0] * outputDim[1]] = (float)((float*)inputData)[(l + left) + (s + above)*(unsigned short)inputDim[0] + (sl + minSlice)*inputDim[0] * inputDim[1]];
-        }
-      }
-    }
-  }
-  else if (inputImage->GetPixelType().GetTypeAsString() == "scalar (short)" || inputImage->GetPixelType().GetTypeAsString() == " (short)")
-  {
-    // copy the data to the cropped image
-    for (unsigned short sl = 0; sl < outputDim[2]; ++sl)
-    {
-      for (unsigned short l = 0; l < outputDim[0]; ++l)
-      {
-        for (unsigned short s = 0; s < outputDim[1]; ++s)
-        {
-          outputData[l + s*(unsigned short)outputDim[0] + sl*outputDim[0] * outputDim[1]] = (float)((short*)inputData)[(l + left) + (s + above)*(unsigned short)inputDim[0] + (sl + minSlice)*inputDim[0] * inputDim[1]];
-        }
-      }
-    }
-  }
-  else if (inputImage->GetPixelType().GetTypeAsString() == "scalar (double)" || inputImage->GetPixelType().GetTypeAsString() == " (double)")
-  {
-    // copy the data to the cropped image
-    for (unsigned short sl = 0; sl < outputDim[2]; ++sl)
-    {
-      for (unsigned short l = 0; l < outputDim[0]; ++l)
-      {
-        for (unsigned short s = 0; s < outputDim[1]; ++s)
-        {
-          outputData[l + s*(unsigned short)outputDim[0] + sl*outputDim[0] * outputDim[1]] = (float)((double*)inputData)[(l + left) + (s + above)*(unsigned short)inputDim[0] + (sl + minSlice)*inputDim[0] * inputDim[1]];
-        }
-      }
-    }
-  }
-  else
-  {
-    MITK_INFO << "Could not determine pixel type";
-  }
-
-  mitk::Image::Pointer output = mitk::Image::New();
-  output->Initialize(mitk::MakeScalarPixelType<float>(), 3, outputDim);
-  output->SetSpacing(inputImage->GetGeometry()->GetSpacing());
-  output->SetImportVolume(outputData, 0, 0, mitk::Image::CopyMemory);
-  delete[] outputData;
-  return output;
+  mitk::CropImageFilter::Pointer cropImageFilter = mitk::CropImageFilter::New();
+  cropImageFilter->SetInput(inputImage);
+  cropImageFilter->SetXPixelsCropStart(left);
+  cropImageFilter->SetXPixelsCropEnd(right);
+  cropImageFilter->SetYPixelsCropStart(above);
+  cropImageFilter->SetYPixelsCropEnd(below);
+  cropImageFilter->SetZPixelsCropStart(zStart);
+  cropImageFilter->SetZPixelsCropEnd(zEnd);
+  cropImageFilter->Update();
+  return cropImageFilter->GetOutput();
 }
 
 mitk::Image::Pointer mitk::PhotoacousticFilterService::ApplyBeamforming(mitk::Image::Pointer inputImage,
   BeamformingSettings::Pointer config, std::string& message, std::function<void(int, std::string)> progressHandle)
 {
   Image::Pointer processedImage = mitk::Image::New();
 
   if (inputImage->GetDimension() != 3)
   {
     mitk::Convert2Dto3DImageFilter::Pointer dimensionImageFilter = mitk::Convert2Dto3DImageFilter::New();
     dimensionImageFilter->SetInput(inputImage);
     dimensionImageFilter->Update();
     processedImage = dimensionImageFilter->GetOutput();
   }
 
-  //config->SetRecordTime(config->GetRecordTime() - (float)(config->GetUpperCutoff()) /
-  //  (float)inputImage->GetDimension(1) * config->GetRecordTime()); // adjust the recorded time lost by cropping
-  //progressHandle(0, "converting image");
-  //if (!config->GetPartial())
-  //{
-  //  config->GetCropBounds()[0] = 0;
-  //  config->GetCropBounds()[1] = inputImage->GetDimension(2) - 1;
-  //}
-  //processedImage = ApplyCropping(inputImage, config->GetUpperCutoff(), 0, 0, 0, config->GetCropBounds()[0], config->GetCropBounds()[1]);
-
   config->GetInputDim()[0] = processedImage->GetDimension(0);
   config->GetInputDim()[1] = processedImage->GetDimension(1);
   config->GetInputDim()[2] = processedImage->GetDimension(2);
 
   // perform the beamforming
   m_BeamformingFilter = mitk::BeamformingFilter::New(config);
   m_BeamformingFilter->SetInput(processedImage);
   m_BeamformingFilter->SetProgressHandle(progressHandle);
   m_BeamformingFilter->UpdateLargestPossibleRegion();
 
   processedImage = m_BeamformingFilter->GetOutput();
   message = m_BeamformingFilter->GetMessageString();
 
   return processedImage;
 }
 
 mitk::Image::Pointer mitk::PhotoacousticFilterService::BandpassFilter(mitk::Image::Pointer data, float recordTime,
   float BPHighPass, float BPLowPass,
   float alphaHighPass, float alphaLowPass)
 {
   bool powerOfTwo = false;
   int finalPower = 0;
   for (int i = 1; pow(2, i) <= data->GetDimension(1); ++i)
   {
     finalPower = i;
     if (pow(2, i) == data->GetDimension(1))
     {
       powerOfTwo = true;
     }
   }
   if (!powerOfTwo)
   {
     unsigned int dim[2] = { data->GetDimension(0), (unsigned int)pow(2,finalPower + 1) };
     data = ApplyResampling(data, dim);
   }
 
   MITK_INFO << data->GetDimension(0);
 
   // do a fourier transform, multiply with an appropriate window for the filter, and transform back
   typedef float PixelType;
   typedef itk::Image< PixelType, 3 > RealImageType;
   RealImageType::Pointer image;
 
   mitk::CastToItkImage(data, image);
 
   typedef itk::FFT1DRealToComplexConjugateImageFilter<RealImageType> ForwardFFTFilterType;
   typedef ForwardFFTFilterType::OutputImageType ComplexImageType;
   ForwardFFTFilterType::Pointer forwardFFTFilter = ForwardFFTFilterType::New();
   forwardFFTFilter->SetInput(image);
   forwardFFTFilter->SetDirection(1);
   try
   {
     forwardFFTFilter->UpdateOutputInformation();
   }
   catch (itk::ExceptionObject & error)
   {
     std::cerr << "Error: " << error << std::endl;
     MITK_WARN << "Bandpass could not be applied";
     return data;
   }
 
   float singleVoxel = 1 / (recordTime / data->GetDimension(1)) / 2 / 1000;
   float cutoffPixelHighPass = std::min(BPHighPass / singleVoxel, (float)data->GetDimension(1) / 2);
   float cutoffPixelLowPass = std::min(BPLowPass / singleVoxel, (float)data->GetDimension(1) / 2 - cutoffPixelHighPass);
 
   RealImageType::Pointer fftMultiplicator = BPFunction(data, cutoffPixelHighPass, cutoffPixelLowPass, alphaHighPass, alphaLowPass);
 
   typedef itk::MultiplyImageFilter< ComplexImageType,
     RealImageType,
     ComplexImageType >
     MultiplyFilterType;
   MultiplyFilterType::Pointer multiplyFilter = MultiplyFilterType::New();
   multiplyFilter->SetInput1(forwardFFTFilter->GetOutput());
   multiplyFilter->SetInput2(fftMultiplicator);
 
   /*itk::ComplexToModulusImageFilter<ComplexImageType, RealImageType>::Pointer toReal = itk::ComplexToModulusImageFilter<ComplexImageType, RealImageType>::New();
   toReal->SetInput(forwardFFTFilter->GetOutput());
   return GrabItkImageMemory(toReal->GetOutput());
   return GrabItkImageMemory(fftMultiplicator);   *///DEBUG
 
   typedef itk::FFT1DComplexConjugateToRealImageFilter< ComplexImageType, RealImageType > InverseFilterType;
   InverseFilterType::Pointer inverseFFTFilter = InverseFilterType::New();
   inverseFFTFilter->SetInput(multiplyFilter->GetOutput());
   inverseFFTFilter->SetDirection(1);
 
   return GrabItkImageMemory(inverseFFTFilter->GetOutput());
 }
 
 itk::Image<float, 3U>::Pointer mitk::PhotoacousticFilterService::BPFunction(mitk::Image::Pointer reference,
   int cutoffFrequencyPixelHighPass,
   int cutoffFrequencyPixelLowPass,
   float alphaHighPass, float alphaLowPass)
 {
   float* imageData = new float[reference->GetDimension(0)*reference->GetDimension(1)];
 
   float width = reference->GetDimension(1) / 2.0 - (float)cutoffFrequencyPixelHighPass - (float)cutoffFrequencyPixelLowPass;
   float center = (float)cutoffFrequencyPixelHighPass / 2.0 + width / 2.0;
 
   for (unsigned int n = 0; n < reference->GetDimension(1); ++n)
   {
     imageData[reference->GetDimension(0)*n] = 0;
   }
   for (int n = 0; n < width; ++n)
   {
     imageData[reference->GetDimension(0)*n] = 1;
     if (n <= (alphaHighPass*(width - 1)) / 2.0)
     {
       if (alphaHighPass > 0.00001)
       {
         imageData[reference->GetDimension(0)*(int)(n + center - (width / 2))] =
           (1 + cos(itk::Math::pi*(2 * n / (alphaHighPass*(width - 1)) - 1))) / 2;
       }
       else
       {
         imageData[reference->GetDimension(0)*(int)(n + center - (width / 2))] = 1;
       }
     }
     else if (n >= (width - 1)*(1 - alphaLowPass / 2)) //???
     {
       if (alphaLowPass > 0.00001)
       {
         imageData[reference->GetDimension(0)*(int)(n + center - (width / 2))] =
           (1 + cos(itk::Math::pi*(2 * n / (alphaLowPass*(width - 1)) + 1 - 2 / alphaLowPass))) / 2;
       }
       else
       {
         imageData[reference->GetDimension(0)*(int)(n + center - (width / 2))] = 1;
       }
     }
     //MITK_INFO << "n:" << n << " is " << imageData[reference->GetDimension(0)*(int)(n + center - (width / 2))];
   }
   MITK_INFO << "width: " << width << ", center: " << center << ", alphaHighPass: " << alphaHighPass << ", alphaLowPass: " << alphaLowPass;
 
   // mirror the first half of the image
   for (unsigned int n = reference->GetDimension(1) / 2; n < reference->GetDimension(1); ++n)
   {
     imageData[reference->GetDimension(0)*n] = imageData[(reference->GetDimension(1) - (n + 1)) * reference->GetDimension(0)];
   }
 
   // copy and paste to all lines
   for (unsigned int line = 1; line < reference->GetDimension(0); ++line)
   {
     for (unsigned int sample = 0; sample < reference->GetDimension(1); ++sample)
     {
       imageData[reference->GetDimension(0)*sample + line] = imageData[reference->GetDimension(0)*sample];
     }
   }
 
   typedef itk::Image< float, 3U >  ImageType;
   ImageType::RegionType region;
   ImageType::IndexType start;
   start.Fill(0);
 
   region.SetIndex(start);
 
   ImageType::SizeType size;
   size[0] = reference->GetDimension(0);
   size[1] = reference->GetDimension(1);
   size[2] = reference->GetDimension(2);
 
   region.SetSize(size);
 
   ImageType::SpacingType SpacingItk;
   SpacingItk[0] = reference->GetGeometry()->GetSpacing()[0];
   SpacingItk[1] = reference->GetGeometry()->GetSpacing()[1];
   SpacingItk[2] = reference->GetGeometry()->GetSpacing()[2];
 
   ImageType::Pointer image = ImageType::New();
   image->SetRegions(region);
   image->Allocate();
   image->FillBuffer(itk::NumericTraits<float>::Zero);
   image->SetSpacing(SpacingItk);
 
   ImageType::IndexType pixelIndex;
 
   for (unsigned int slice = 0; slice < reference->GetDimension(2); ++slice)
   {
     for (unsigned int line = 0; line < reference->GetDimension(0); ++line)
     {
       for (unsigned int sample = 0; sample < reference->GetDimension(1); ++sample)
       {
         pixelIndex[0] = line;
         pixelIndex[1] = sample;
         pixelIndex[2] = slice;
 
         image->SetPixel(pixelIndex, imageData[line + sample*reference->GetDimension(0)]);
       }
     }
   }
 
   delete[] imageData;
 
   return image;
 }
diff --git a/Plugins/org.mitk.gui.qt.photoacoustics.imageprocessing/src/internal/PAImageProcessing.cpp b/Plugins/org.mitk.gui.qt.photoacoustics.imageprocessing/src/internal/PAImageProcessing.cpp
index 7e413d3e5a..b5827dcdab 100644
--- a/Plugins/org.mitk.gui.qt.photoacoustics.imageprocessing/src/internal/PAImageProcessing.cpp
+++ b/Plugins/org.mitk.gui.qt.photoacoustics.imageprocessing/src/internal/PAImageProcessing.cpp
@@ -1,1160 +1,1160 @@
 /*===================================================================
 
 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 "PAImageProcessing.h"
 
 // Qt
 #include <QMessageBox>
 #include <QApplication>
 #include <QMetaType>
 #include <QFileDialog>
 
 //mitk image
 #include <mitkImage.h>
 #include "mitkPhotoacousticFilterService.h"
 #include "mitkBeamformingFilter.h"
 
 //other
 #include <thread>
 #include <functional>
 #include <mitkIOUtil.h>
 
 const std::string PAImageProcessing::VIEW_ID = "org.mitk.views.paimageprocessing";
 
 PAImageProcessing::PAImageProcessing() : m_ResampleSpacing(0), m_UseLogfilter(false), m_FilterBank(mitk::PhotoacousticFilterService::New())
 {
   qRegisterMetaType<mitk::Image::Pointer>();
   qRegisterMetaType<std::string>();
 }
 
 void PAImageProcessing::SetFocus()
 {
   m_Controls.buttonApplyBModeFilter->setFocus();
 }
 
 void PAImageProcessing::CreateQtPartControl(QWidget *parent)
 {
   BFconfig = mitk::BeamformingSettings::New();
   // create GUI widgets from the Qt Designer's .ui file
   m_Controls.setupUi(parent);
   connect(m_Controls.buttonApplyBModeFilter, SIGNAL(clicked()), this, SLOT(StartBmodeThread()));
   connect(m_Controls.DoResampling, SIGNAL(clicked()), this, SLOT(UseResampling()));
   connect(m_Controls.Logfilter, SIGNAL(clicked()), this, SLOT(UseLogfilter()));
   connect(m_Controls.ResamplingValue, SIGNAL(valueChanged(double)), this, SLOT(SetResampling()));
   connect(m_Controls.buttonApplyBeamforming, SIGNAL(clicked()), this, SLOT(StartBeamformingThread()));
   connect(m_Controls.buttonApplyCropFilter, SIGNAL(clicked()), this, SLOT(StartCropThread()));
   connect(m_Controls.buttonApplyBandpass, SIGNAL(clicked()), this, SLOT(StartBandpassThread()));
   connect(m_Controls.UseImageSpacing, SIGNAL(clicked()), this, SLOT(UseImageSpacing()));
   connect(m_Controls.ScanDepth, SIGNAL(valueChanged(double)), this, SLOT(UpdateImageInfo()));
   connect(m_Controls.SpeedOfSound, SIGNAL(valueChanged(double)), this, SLOT(UpdateImageInfo()));
   connect(m_Controls.SpeedOfSound, SIGNAL(valueChanged(double)), this, SLOT(ChangedSOSBeamforming()));
   connect(m_Controls.BPSpeedOfSound, SIGNAL(valueChanged(double)), this, SLOT(ChangedSOSBandpass()));
   connect(m_Controls.Samples, SIGNAL(valueChanged(int)), this, SLOT(UpdateImageInfo()));
   connect(m_Controls.UseImageSpacing, SIGNAL(clicked()), this, SLOT(UpdateImageInfo()));
   connect(m_Controls.boundLow, SIGNAL(valueChanged(int)), this, SLOT(LowerSliceBoundChanged()));
   connect(m_Controls.boundHigh, SIGNAL(valueChanged(int)), this, SLOT(UpperSliceBoundChanged()));
   connect(m_Controls.Partial, SIGNAL(clicked()), this, SLOT(SliceBoundsEnabled()));
   connect(m_Controls.BatchProcessing, SIGNAL(clicked()), this, SLOT(BatchProcessing()));
   connect(m_Controls.StepBeamforming, SIGNAL(clicked()), this, SLOT(UpdateSaveBoxes()));
   connect(m_Controls.StepCropping, SIGNAL(clicked()), this, SLOT(UpdateSaveBoxes()));
   connect(m_Controls.StepBandpass, SIGNAL(clicked()), this, SLOT(UpdateSaveBoxes()));
   connect(m_Controls.StepBMode, SIGNAL(clicked()), this, SLOT(UpdateSaveBoxes()));
 
   UpdateSaveBoxes();
   m_Controls.DoResampling->setChecked(false);
   m_Controls.ResamplingValue->setEnabled(false);
   m_Controls.progressBar->setMinimum(0);
   m_Controls.progressBar->setMaximum(100);
   m_Controls.progressBar->setVisible(false);
   m_Controls.UseImageSpacing->setToolTip("Image spacing of y-Axis must be in us, x-Axis in mm.");
   m_Controls.UseImageSpacing->setToolTipDuration(5000);
   m_Controls.ProgressInfo->setVisible(false);
   m_Controls.UseBP->hide();
   m_Controls.UseGPUBmode->hide();
 
 #ifndef PHOTOACOUSTICS_USE_GPU
   m_Controls.UseGPUBf->setEnabled(false);
   m_Controls.UseGPUBf->setChecked(false);
   m_Controls.UseGPUBmode->setEnabled(false);
   m_Controls.UseGPUBmode->setChecked(false);
 #endif
 
   UseImageSpacing();
 }
 
 void PAImageProcessing::ChangedSOSBandpass()
 {
   m_Controls.SpeedOfSound->setValue(m_Controls.BPSpeedOfSound->value());
 }
 
 void PAImageProcessing::ChangedSOSBeamforming()
 {
   m_Controls.BPSpeedOfSound->setValue(m_Controls.SpeedOfSound->value());
 }
 
 std::vector<std::string> splitpath(
   const std::string& str
   , const std::set<char> delimiters)
 {
   std::vector<std::string> result;
 
   char const* pch = str.c_str();
   char const* start = pch;
   for (; *pch; ++pch)
   {
     if (delimiters.find(*pch) != delimiters.end())
     {
       if (start != pch)
       {
         std::string str(start, pch);
         result.push_back(str);
       }
       else
       {
         result.push_back("");
       }
       start = pch + 1;
     }
   }
   result.push_back(start);
 
   return result;
 }
 
 void PAImageProcessing::UpdateSaveBoxes()
 {
   if (m_Controls.StepBeamforming->isChecked())
     m_Controls.SaveBeamforming->setEnabled(true);
   else
     m_Controls.SaveBeamforming->setEnabled(false);
 
   if (m_Controls.StepCropping->isChecked())
     m_Controls.SaveCropping->setEnabled(true);
   else
     m_Controls.SaveCropping->setEnabled(false);
 
   if (m_Controls.StepBandpass->isChecked())
     m_Controls.SaveBandpass->setEnabled(true);
   else
     m_Controls.SaveBandpass->setEnabled(false);
 
   if (m_Controls.StepBMode->isChecked())
     m_Controls.SaveBMode->setEnabled(true);
   else
     m_Controls.SaveBMode->setEnabled(false);
 }
 
 void PAImageProcessing::BatchProcessing()
 {
   QFileDialog LoadDialog(nullptr, "Select Files to be processed");
   LoadDialog.setFileMode(QFileDialog::FileMode::ExistingFiles);
   LoadDialog.setNameFilter(tr("Images (*.nrrd)"));
   LoadDialog.setViewMode(QFileDialog::Detail);
 
   QStringList fileNames;
   if (LoadDialog.exec())
     fileNames = LoadDialog.selectedFiles();
 
   QString saveDir = QFileDialog::getExistingDirectory(nullptr, tr("Select Directory To Save To"),
     "",
     QFileDialog::ShowDirsOnly
     | QFileDialog::DontResolveSymlinks);
 
   DisableControls();
 
   std::set<char> delims{ '/' };
 
   bool doSteps[] = { m_Controls.StepBeamforming->isChecked(), m_Controls.StepCropping->isChecked() , m_Controls.StepBandpass->isChecked(), m_Controls.StepBMode->isChecked() };
   bool saveSteps[] = { m_Controls.SaveBeamforming->isChecked(), m_Controls.SaveCropping->isChecked() , m_Controls.SaveBandpass->isChecked(), m_Controls.SaveBMode->isChecked() };
 
   for (int fileNumber = 0; fileNumber < fileNames.size(); ++fileNumber)
   {
     m_Controls.progressBar->setValue(0);
     m_Controls.progressBar->setVisible(true);
     m_Controls.ProgressInfo->setVisible(true);
     m_Controls.ProgressInfo->setText("loading file");
 
     QString filename = fileNames.at(fileNumber);
     auto split = splitpath(filename.toStdString(), delims);
     std::string imageName = split.at(split.size() - 1);
 
     // remove ".nrrd"
     imageName = imageName.substr(0, imageName.size() - 5);
 
     mitk::Image::Pointer image = mitk::IOUtil::Load<mitk::Image>(filename.toStdString().c_str());
 
     UpdateBFSettings(image);
     // Beamforming
     if (doSteps[0])
     {
       std::function<void(int, std::string)> progressHandle = [this](int progress, std::string progressInfo) {
         this->UpdateProgress(progress, progressInfo);
       };
       m_Controls.progressBar->setValue(100);
       std::string errorMessage = "";
 
       image = m_FilterBank->ApplyBeamforming(image, BFconfig, errorMessage, progressHandle);
 
       if (saveSteps[0])
       {
         std::string saveFileName = saveDir.toStdString() + "/" + imageName + " beamformed" + ".nrrd";
         mitk::IOUtil::Save(image, saveFileName);
       }
     }
 
     // Cropping
     if (doSteps[1])
     {
       m_Controls.ProgressInfo->setText("cropping image");
 
-      image = m_FilterBank->ApplyCropping(image, m_Controls.CutoffAbove->value(), m_Controls.CutoffBelow->value(), 0, 0, 0, image->GetDimension(2) - 1);
+      image = m_FilterBank->ApplyCropping(image, m_Controls.CutoffAbove->value(), m_Controls.CutoffBelow->value(), 0, 0, 0, 0);
 
       if (saveSteps[1])
       {
         std::string saveFileName = saveDir.toStdString() + "/" + imageName + " cropped" + ".nrrd";
         mitk::IOUtil::Save(image, saveFileName);
       }
     }
 
     // Bandpass
     if (doSteps[2])
     {
       m_Controls.ProgressInfo->setText("applying bandpass");
       float recordTime = image->GetDimension(1)*image->GetGeometry()->GetSpacing()[1] / 1000 / m_Controls.BPSpeedOfSound->value();
       // add a safeguard so the program does not chrash when applying a Bandpass that reaches out of the bounds of the image
       float maxFrequency = 1 / (recordTime / image->GetDimension(1)) * image->GetDimension(1) / 2 / 2 / 1000;
       float BPHighPass = 1000000 * m_Controls.BPhigh->value(); // [Hz]
       float BPLowPass = maxFrequency - 1000000 * m_Controls.BPlow->value(); // [Hz]
 
       if (BPLowPass > maxFrequency && m_Controls.UseBP->isChecked())
       {
         QMessageBox Msgbox;
         Msgbox.setText("LowPass too low, disabled it.");
         Msgbox.exec();
 
         BPLowPass = 0;
       }
       if (BPLowPass < 0 && m_Controls.UseBP->isChecked())
       {
         QMessageBox Msgbox;
         Msgbox.setText("LowPass too high, disabled it.");
         Msgbox.exec();
 
         BPLowPass = 0;
       }
       if (BPHighPass > maxFrequency &&  m_Controls.UseBP->isChecked())
       {
         QMessageBox Msgbox;
         Msgbox.setText("HighPass too high, disabled it.");
         Msgbox.exec();
 
         BPHighPass = 0;
       }
       if (BPHighPass > maxFrequency - BFconfig->GetBPLowPass())
       {
         QMessageBox Msgbox;
         Msgbox.setText("HighPass higher than LowPass, disabled both.");
         Msgbox.exec();
 
         BPHighPass = 0;
         BPLowPass = 0;
       }
 
       image = m_FilterBank->BandpassFilter(image, recordTime, BPHighPass, BPLowPass,
         m_Controls.BPFalloffHigh->value(),
         m_Controls.BPFalloffLow->value());
 
       if (saveSteps[2])
       {
         std::string saveFileName = saveDir.toStdString() + "/" + imageName + " bandpassed" + ".nrrd";
         mitk::IOUtil::Save(image, saveFileName);
       }
     }
     // Bmode
     if (doSteps[3])
     {
       m_Controls.ProgressInfo->setText("applying bmode filter");
       bool useGPU = m_Controls.UseGPUBmode->isChecked();
 
       if (m_Controls.BModeMethod->currentText() == "Absolute Filter")
         image = m_FilterBank->ApplyBmodeFilter(image, mitk::PhotoacousticFilterService::BModeMethod::Abs, useGPU, m_UseLogfilter, m_ResampleSpacing);
       else if (m_Controls.BModeMethod->currentText() == "Envelope Detection")
         image = m_FilterBank->ApplyBmodeFilter(image, mitk::PhotoacousticFilterService::BModeMethod::EnvelopeDetection, useGPU, m_UseLogfilter, m_ResampleSpacing);
 
       if (saveSteps[3])
       {
         std::string saveFileName = saveDir.toStdString() + "/" + imageName + " bmode" + ".nrrd";
         mitk::IOUtil::Save(image, saveFileName);
       }
     }
     m_Controls.progressBar->setVisible(false);
   }
 
   EnableControls();
 }
 
 void PAImageProcessing::StartBeamformingThread()
 {
   QList<mitk::DataNode::Pointer> nodes = this->GetDataManagerSelection();
   if (nodes.empty()) return;
 
   mitk::DataStorage::Pointer storage = this->GetDataStorage();
 
   mitk::DataNode::Pointer node = nodes.front();
 
   if (!node)
   {
     // Nothing selected. Inform the user and return
     QMessageBox::information(NULL, "Template", "Please load and select an image before starting image processing.");
     return;
   }
 
   mitk::BaseData* data = node->GetData();
   if (data)
   {
     // test if this data item is an image or not (could also be a surface or something totally different)
     mitk::Image* image = dynamic_cast<mitk::Image*>(data);
     if (image)
     {
       UpdateBFSettings(image);
       std::stringstream message;
       std::string name;
       message << "Performing beamforming for image ";
       if (node->GetName(name))
       {
         // a property called "name" was found for this DataNode
         message << "'" << name << "'";
         m_OldNodeName = name;
       }
       else
         m_OldNodeName = " ";
 
       message << ".";
       MITK_INFO << message.str();
 
       m_Controls.progressBar->setValue(0);
       m_Controls.progressBar->setVisible(true);
       m_Controls.ProgressInfo->setVisible(true);
       m_Controls.ProgressInfo->setText("started");
       m_Controls.buttonApplyBeamforming->setText("working...");
       DisableControls();
 
       BeamformingThread *thread = new BeamformingThread();
       connect(thread, &BeamformingThread::result, this, &PAImageProcessing::HandleBeamformingResults);
       connect(thread, &BeamformingThread::updateProgress, this, &PAImageProcessing::UpdateProgress);
       connect(thread, &BeamformingThread::message, this, &PAImageProcessing::PAMessageBox);
       connect(thread, &BeamformingThread::finished, thread, &QObject::deleteLater);
 
       thread->setConfig(BFconfig);
       thread->setInputImage(image);
       thread->setFilterBank(m_FilterBank);
 
       MITK_INFO << "Started new thread for Beamforming";
       thread->start();
     }
   }
 }
 
 void PAImageProcessing::HandleBeamformingResults(mitk::Image::Pointer image)
 {
   MITK_INFO << "Handle Beamforming results";
   auto newNode = mitk::DataNode::New();
   newNode->SetData(image);
 
   // name the new Data node
   std::stringstream newNodeName;
 
   newNodeName << m_OldNodeName << " ";
 
   if (BFconfig->GetAlgorithm() == mitk::BeamformingSettings::BeamformingAlgorithm::DAS)
     newNodeName << "DAS bf, ";
   else if (BFconfig->GetAlgorithm() == mitk::BeamformingSettings::BeamformingAlgorithm::DMAS)
     newNodeName << "DMAS bf, ";
 
   if (BFconfig->GetDelayCalculationMethod() == mitk::BeamformingSettings::DelayCalc::QuadApprox)
     newNodeName << "q. delay";
   if (BFconfig->GetDelayCalculationMethod() == mitk::BeamformingSettings::DelayCalc::Spherical)
     newNodeName << "s. delay";
 
   newNode->SetName(newNodeName.str());
 
   // update level window for the current dynamic range
   mitk::LevelWindow levelWindow;
   newNode->GetLevelWindow(levelWindow);
   levelWindow.SetAuto(image, true, true);
   newNode->SetLevelWindow(levelWindow);
 
   // add new node to data storage
   this->GetDataStorage()->Add(newNode);
 
   // disable progress bar
   m_Controls.progressBar->setVisible(false);
   m_Controls.ProgressInfo->setVisible(false);
   m_Controls.buttonApplyBeamforming->setText("Apply Beamforming");
   EnableControls();
 
   // update rendering
   mitk::RenderingManager::GetInstance()->InitializeViews(image->GetGeometry(), mitk::RenderingManager::REQUEST_UPDATE_ALL, true);
   mitk::RenderingManager::GetInstance()->RequestUpdateAll();
 }
 
 void PAImageProcessing::StartBmodeThread()
 {
   QList<mitk::DataNode::Pointer> nodes = this->GetDataManagerSelection();
   if (nodes.empty()) return;
 
   mitk::DataStorage::Pointer storage = this->GetDataStorage();
 
   mitk::DataNode::Pointer node = nodes.front();
 
   if (!node)
   {
     // Nothing selected. Inform the user and return
     QMessageBox::information(NULL, "Template", "Please load and select an image before starting image processing.");
     return;
   }
 
   mitk::BaseData* data = node->GetData();
   if (data)
   {
     // test if this data item is an image or not (could also be a surface or something totally different)
     mitk::Image* image = dynamic_cast<mitk::Image*>(data);
     if (image)
     {
       UpdateBFSettings(image);
       std::stringstream message;
       std::string name;
       message << "Performing image processing for image ";
       if (node->GetName(name))
       {
         // a property called "name" was found for this DataNode
         message << "'" << name << "'";
         m_OldNodeName = name;
       }
       else
         m_OldNodeName = " ";
 
       message << ".";
       MITK_INFO << message.str();
 
       m_Controls.buttonApplyBModeFilter->setText("working...");
       DisableControls();
 
       BmodeThread *thread = new BmodeThread();
       connect(thread, &BmodeThread::result, this, &PAImageProcessing::HandleBmodeResults);
       connect(thread, &BmodeThread::finished, thread, &QObject::deleteLater);
 
       bool useGPU = m_Controls.UseGPUBmode->isChecked();
 
       if (m_Controls.BModeMethod->currentText() == "Absolute Filter")
         thread->setConfig(m_UseLogfilter, m_ResampleSpacing, mitk::PhotoacousticFilterService::BModeMethod::Abs, useGPU);
       else if (m_Controls.BModeMethod->currentText() == "Envelope Detection")
         thread->setConfig(m_UseLogfilter, m_ResampleSpacing, mitk::PhotoacousticFilterService::BModeMethod::EnvelopeDetection, useGPU);
       thread->setInputImage(image);
       thread->setFilterBank(m_FilterBank);
 
       MITK_INFO << "Started new thread for Image Processing";
       thread->start();
     }
   }
 }
 
 void PAImageProcessing::HandleBmodeResults(mitk::Image::Pointer image)
 {
   auto newNode = mitk::DataNode::New();
   newNode->SetData(image);
 
   // name the new Data node
   std::stringstream newNodeName;
   newNodeName << m_OldNodeName << " ";
   newNodeName << "B-Mode";
 
   newNode->SetName(newNodeName.str());
 
   // update level window for the current dynamic range
   mitk::LevelWindow levelWindow;
   newNode->GetLevelWindow(levelWindow);
   auto data = newNode->GetData();
   levelWindow.SetAuto(dynamic_cast<mitk::Image*>(data), true, true);
   newNode->SetLevelWindow(levelWindow);
 
   // add new node to data storage
   this->GetDataStorage()->Add(newNode);
 
   // disable progress bar
   m_Controls.progressBar->setVisible(false);
   m_Controls.buttonApplyBModeFilter->setText("Apply B-mode Filter");
   EnableControls();
 
   // update rendering
   mitk::RenderingManager::GetInstance()->InitializeViews(
     dynamic_cast<mitk::Image*>(data)->GetGeometry(), mitk::RenderingManager::REQUEST_UPDATE_ALL, true);
   mitk::RenderingManager::GetInstance()->RequestUpdateAll();
 }
 
 void PAImageProcessing::StartCropThread()
 {
   QList<mitk::DataNode::Pointer> nodes = this->GetDataManagerSelection();
   if (nodes.empty()) return;
 
   mitk::DataStorage::Pointer storage = this->GetDataStorage();
 
   mitk::DataNode::Pointer node = nodes.front();
 
   if (!node)
   {
     // Nothing selected. Inform the user and return
     QMessageBox::information(NULL, "Template", "Please load and select an image before starting image cropping.");
     return;
   }
 
   mitk::BaseData* data = node->GetData();
   if (data)
   {
     // test if this data item is an image or not (could also be a surface or something totally different)
     mitk::Image* image = dynamic_cast<mitk::Image*>(data);
     if (image)
     {
       UpdateBFSettings(image);
       std::stringstream message;
       std::string name;
       message << "Performing image cropping for image ";
       if (node->GetName(name))
       {
         // a property called "name" was found for this DataNode
         message << "'" << name << "'";
         m_OldNodeName = name;
       }
       else
         m_OldNodeName = " ";
 
       message << ".";
       MITK_INFO << message.str();
 
       m_Controls.buttonApplyCropFilter->setText("working...");
       DisableControls();
 
       CropThread *thread = new CropThread();
       connect(thread, &CropThread::result, this, &PAImageProcessing::HandleCropResults);
       connect(thread, &CropThread::finished, thread, &QObject::deleteLater);
 
       thread->setConfig(m_Controls.CutoffAbove->value(), m_Controls.CutoffBelow->value(), 0, image->GetDimension(2) - 1);
       thread->setInputImage(image);
       thread->setFilterBank(m_FilterBank);
 
       MITK_INFO << "Started new thread for Image Cropping";
       thread->start();
     }
   }
 }
 
 void PAImageProcessing::HandleCropResults(mitk::Image::Pointer image)
 {
   auto newNode = mitk::DataNode::New();
   newNode->SetData(image);
 
   // name the new Data node
   std::stringstream newNodeName;
   newNodeName << m_OldNodeName << " ";
   newNodeName << "Cropped";
 
   newNode->SetName(newNodeName.str());
 
   // update level window for the current dynamic range
   mitk::LevelWindow levelWindow;
   newNode->GetLevelWindow(levelWindow);
   auto data = newNode->GetData();
   levelWindow.SetAuto(dynamic_cast<mitk::Image*>(data), true, true);
   newNode->SetLevelWindow(levelWindow);
 
   // add new node to data storage
   this->GetDataStorage()->Add(newNode);
 
   m_Controls.buttonApplyCropFilter->setText("Apply Crop Filter");
   EnableControls();
 
   // update rendering
   mitk::RenderingManager::GetInstance()->InitializeViews(
     dynamic_cast<mitk::Image*>(data)->GetGeometry(), mitk::RenderingManager::REQUEST_UPDATE_ALL, true);
   mitk::RenderingManager::GetInstance()->RequestUpdateAll();
 }
 
 void PAImageProcessing::StartBandpassThread()
 {
   QList<mitk::DataNode::Pointer> nodes = this->GetDataManagerSelection();
   if (nodes.empty()) return;
 
   mitk::DataStorage::Pointer storage = this->GetDataStorage();
 
   mitk::DataNode::Pointer node = nodes.front();
 
   if (!node)
   {
     // Nothing selected. Inform the user and return
     QMessageBox::information(NULL, "Template", "Please load and select an image before starting image cropping.");
     return;
   }
 
   mitk::BaseData* data = node->GetData();
   if (data)
   {
     // test if this data item is an image or not (could also be a surface or something totally different)
     mitk::Image* image = dynamic_cast<mitk::Image*>(data);
     if (image)
     {
       UpdateBFSettings(image);
       std::stringstream message;
       std::string name;
       message << "Performing Bandpass filter on image ";
       if (node->GetName(name))
       {
         // a property called "name" was found for this DataNode
         message << "'" << name << "'";
         m_OldNodeName = name;
       }
       else
         m_OldNodeName = " ";
 
       message << ".";
       MITK_INFO << message.str();
 
       m_Controls.buttonApplyBandpass->setText("working...");
       DisableControls();
 
       BandpassThread *thread = new BandpassThread();
       connect(thread, &BandpassThread::result, this, &PAImageProcessing::HandleBandpassResults);
       connect(thread, &BandpassThread::finished, thread, &QObject::deleteLater);
 
       float recordTime = image->GetDimension(1)*image->GetGeometry()->GetSpacing()[1] / 1000 / m_Controls.BPSpeedOfSound->value();
 
       // add a safeguard so the program does not chrash when applying a Bandpass that reaches out of the bounds of the image
       float maxFrequency = 1 / (recordTime / image->GetDimension(1)) * image->GetDimension(1) / 2 / 2 / 1000;
       float BPHighPass = 1000000 * m_Controls.BPhigh->value(); // [Hz]
       float BPLowPass = maxFrequency - 1000000 * m_Controls.BPlow->value(); // [Hz]
 
       if (BPLowPass > maxFrequency && m_Controls.UseBP->isChecked())
       {
         QMessageBox Msgbox;
         Msgbox.setText("LowPass too low, disabled it.");
         Msgbox.exec();
 
         BPLowPass = 0;
       }
       if (BPLowPass < 0 && m_Controls.UseBP->isChecked())
       {
         QMessageBox Msgbox;
         Msgbox.setText("LowPass too high, disabled it.");
         Msgbox.exec();
 
         BPLowPass = 0;
       }
       if (BPHighPass > maxFrequency &&  m_Controls.UseBP->isChecked())
       {
         QMessageBox Msgbox;
         Msgbox.setText("HighPass too high, disabled it.");
         Msgbox.exec();
 
         BPHighPass = 0;
       }
       if (BPHighPass > maxFrequency - BFconfig->GetBPLowPass())
       {
         QMessageBox Msgbox;
         Msgbox.setText("HighPass higher than LowPass, disabled both.");
         Msgbox.exec();
 
         BPHighPass = 0;
         BPLowPass = 0;
       }
 
       thread->setConfig(BPHighPass, BPLowPass, m_Controls.BPFalloffLow->value(), m_Controls.BPFalloffHigh->value(), recordTime);
       thread->setInputImage(image);
       thread->setFilterBank(m_FilterBank);
 
       MITK_INFO << "Started new thread for Bandpass filter";
       thread->start();
     }
   }
 }
 
 void PAImageProcessing::HandleBandpassResults(mitk::Image::Pointer image)
 {
   auto newNode = mitk::DataNode::New();
   newNode->SetData(image);
 
   // name the new Data node
   std::stringstream newNodeName;
   newNodeName << m_OldNodeName << " ";
   newNodeName << "Bandpassed";
 
   newNode->SetName(newNodeName.str());
 
   // update level window for the current dynamic range
   mitk::LevelWindow levelWindow;
   newNode->GetLevelWindow(levelWindow);
   auto data = newNode->GetData();
   levelWindow.SetAuto(dynamic_cast<mitk::Image*>(data), true, true);
   newNode->SetLevelWindow(levelWindow);
 
   // add new node to data storage
   this->GetDataStorage()->Add(newNode);
 
   m_Controls.buttonApplyBandpass->setText("Apply Bandpass");
   EnableControls();
 
   // update rendering
   mitk::RenderingManager::GetInstance()->InitializeViews(
     dynamic_cast<mitk::Image*>(data)->GetGeometry(), mitk::RenderingManager::REQUEST_UPDATE_ALL, true);
   mitk::RenderingManager::GetInstance()->RequestUpdateAll();
 }
 
 void PAImageProcessing::SliceBoundsEnabled()
 {
   if (!m_Controls.Partial->isChecked())
   {
     m_Controls.boundLow->setEnabled(false);
     m_Controls.boundHigh->setEnabled(false);
     return;
   }
   else
   {
     m_Controls.boundLow->setEnabled(true);
     m_Controls.boundHigh->setEnabled(true);
   }
 }
 
 void PAImageProcessing::UpperSliceBoundChanged()
 {
   if (m_Controls.boundLow->value() > m_Controls.boundHigh->value())
   {
     m_Controls.boundLow->setValue(m_Controls.boundHigh->value());
   }
 }
 
 void PAImageProcessing::LowerSliceBoundChanged()
 {
   if (m_Controls.boundLow->value() > m_Controls.boundHigh->value())
   {
     m_Controls.boundHigh->setValue(m_Controls.boundLow->value());
   }
 }
 
 void PAImageProcessing::UpdateProgress(int progress, std::string progressInfo)
 {
   if (progress < 100)
     m_Controls.progressBar->setValue(progress);
   else
     m_Controls.progressBar->setValue(100);
   m_Controls.ProgressInfo->setText(progressInfo.c_str());
   qApp->processEvents();
 }
 
 void PAImageProcessing::PAMessageBox(std::string message)
 {
   if (0 != message.compare("noMessage"))
   {
     QMessageBox msgBox;
     msgBox.setText(message.c_str());
     msgBox.exec();
   }
 }
 
 void PAImageProcessing::UpdateImageInfo()
 {
   QList<mitk::DataNode::Pointer> nodes = this->GetDataManagerSelection();
   if (nodes.empty()) return;
 
   mitk::DataNode::Pointer node = nodes.front();
 
   if (!node)
   {
     // Nothing selected
     return;
   }
 
   mitk::BaseData* data = node->GetData();
   if (data)
   {
     // test if this data item is an image or not (could also be a surface or something totally different)
     mitk::Image* image = dynamic_cast<mitk::Image*>(data);
 
     if (image)
     {
       // beamforming configs
       if (m_Controls.UseImageSpacing->isChecked())
       {
         m_Controls.ElementCount->setValue(image->GetDimension(0));
         m_Controls.Pitch->setValue(image->GetGeometry()->GetSpacing()[0]);
       }
 
       m_Controls.boundLow->setMaximum(image->GetDimension(2) - 1);
       m_Controls.boundHigh->setMaximum(image->GetDimension(2) - 1);
 
       UpdateBFSettings(image);
 
       std::stringstream frequency;
       float maxFrequency = (1 / BFconfig->GetTimeSpacing()) * image->GetDimension(1) / 2 / 2 / 1000;
       frequency << maxFrequency / 1000000; //[MHz]
       frequency << "MHz";
 
       m_Controls.BPhigh->setMaximum(maxFrequency / 1000000);
       m_Controls.BPlow->setMaximum(maxFrequency / 1000000);
 
       frequency << " is the maximal allowed frequency for the selected image.";
       m_Controls.BPhigh->setToolTip(frequency.str().c_str());
       m_Controls.BPlow->setToolTip(frequency.str().c_str());
       m_Controls.BPhigh->setToolTipDuration(5000);
       m_Controls.BPlow->setToolTipDuration(5000);
     }
   }
 }
 
 void PAImageProcessing::OnSelectionChanged(berry::IWorkbenchPart::Pointer /*source*/,
   const QList<mitk::DataNode::Pointer>& nodes)
 {
   // iterate all selected objects, adjust warning visibility
   foreach(mitk::DataNode::Pointer node, nodes)
   {
     if (node.IsNotNull() && dynamic_cast<mitk::Image*>(node->GetData()))
     {
       m_Controls.labelWarning->setVisible(false);
       m_Controls.buttonApplyBModeFilter->setEnabled(true);
       m_Controls.labelWarning2->setVisible(false);
       m_Controls.buttonApplyCropFilter->setEnabled(true);
       m_Controls.labelWarning3->setVisible(false);
       m_Controls.buttonApplyBandpass->setEnabled(true);
       m_Controls.labelWarning4->setVisible(false);
       m_Controls.buttonApplyBeamforming->setEnabled(true);
       UpdateImageInfo();
       return;
     }
   }
   m_Controls.labelWarning->setVisible(true);
   m_Controls.buttonApplyBModeFilter->setEnabled(false);
   m_Controls.labelWarning2->setVisible(true);
   m_Controls.buttonApplyCropFilter->setEnabled(false);
   m_Controls.labelWarning3->setVisible(true);
   m_Controls.buttonApplyBandpass->setEnabled(false);
   m_Controls.labelWarning4->setVisible(true);
   m_Controls.buttonApplyBeamforming->setEnabled(false);
 }
 
 void PAImageProcessing::UseResampling()
 {
   if (m_Controls.DoResampling->isChecked())
   {
     m_Controls.ResamplingValue->setEnabled(true);
     m_ResampleSpacing = m_Controls.ResamplingValue->value();
   }
   else
   {
     m_Controls.ResamplingValue->setEnabled(false);
     m_ResampleSpacing = 0;
   }
 }
 
 void PAImageProcessing::UseLogfilter()
 {
   m_UseLogfilter = m_Controls.Logfilter->isChecked();
 }
 
 void PAImageProcessing::SetResampling()
 {
   m_ResampleSpacing = m_Controls.ResamplingValue->value();
 }
 
 void PAImageProcessing::UpdateBFSettings(mitk::Image::Pointer image)
 {
   if ("DAS" == m_Controls.BFAlgorithm->currentText())
     BFconfig->SetAlgorithm(mitk::BeamformingSettings::BeamformingAlgorithm::DAS);
   else if ("DMAS" == m_Controls.BFAlgorithm->currentText())
     BFconfig->SetAlgorithm(mitk::BeamformingSettings::BeamformingAlgorithm::DMAS);
   else if ("sDMAS" == m_Controls.BFAlgorithm->currentText())
     BFconfig->SetAlgorithm(mitk::BeamformingSettings::BeamformingAlgorithm::sDMAS);
 
   if ("Quad. Approx." == m_Controls.DelayCalculation->currentText())
   {
     BFconfig->SetDelayCalculationMethod(mitk::BeamformingSettings::DelayCalc::QuadApprox);
   }
   else if ("Spherical Wave" == m_Controls.DelayCalculation->currentText())
   {
     BFconfig->SetDelayCalculationMethod(mitk::BeamformingSettings::DelayCalc::Spherical);
   }
 
   if ("Von Hann" == m_Controls.Apodization->currentText())
   {
     BFconfig->SetApod(mitk::BeamformingSettings::Apodization::Hann);
   }
   else if ("Hamming" == m_Controls.Apodization->currentText())
   {
     BFconfig->SetApod(mitk::BeamformingSettings::Apodization::Hamm);
   }
   else if ("Box" == m_Controls.Apodization->currentText())
   {
     BFconfig->SetApod(mitk::BeamformingSettings::Apodization::Box);
   }
 
   BFconfig->SetPitchInMeters(m_Controls.Pitch->value() / 1000); // [m]
   BFconfig->SetSpeedOfSound(m_Controls.SpeedOfSound->value()); // [m/s]
   BFconfig->SetSamplesPerLine(m_Controls.Samples->value());
   BFconfig->SetReconstructionLines(m_Controls.Lines->value());
   BFconfig->SetTransducerElements(m_Controls.ElementCount->value());
   BFconfig->SetApodizationArraySize(m_Controls.Lines->value());
   BFconfig->SetAngle(m_Controls.Angle->value()); // [deg]
   BFconfig->SetUseBP(m_Controls.UseBP->isChecked());
   BFconfig->SetUseGPU(m_Controls.UseGPUBf->isChecked());
 
   if (m_Controls.UseImageSpacing->isChecked())
   {
     BFconfig->SetTimeSpacing(image->GetGeometry()->GetSpacing()[1] / 1000000);
     MITK_INFO << "Calculated Scan Depth of " << (image->GetDimension(1)*image->GetGeometry()->GetSpacing()[1] / 1000000) * BFconfig->GetSpeedOfSound() * 100 / 2 << "cm";
   }
   else
   {
     BFconfig->SetTimeSpacing((2 * m_Controls.ScanDepth->value() / 1000 / BFconfig->GetSpeedOfSound()) / image->GetDimension(1));
   }
 
   if ("US Image" == m_Controls.ImageType->currentText())
   {
     BFconfig->SetIsPhotoacousticImage(false);
   }
   else if ("PA Image" == m_Controls.ImageType->currentText())
   {
     BFconfig->SetIsPhotoacousticImage(true);
   }
 
   BFconfig->SetPartial(m_Controls.Partial->isChecked());
   BFconfig->GetCropBounds()[0] = m_Controls.boundLow->value();
   BFconfig->GetCropBounds()[1] = m_Controls.boundHigh->value();
 }
 
 void PAImageProcessing::EnableControls()
 {
   m_Controls.BatchProcessing->setEnabled(true);
   m_Controls.StepBeamforming->setEnabled(true);
   m_Controls.StepBandpass->setEnabled(true);
   m_Controls.StepCropping->setEnabled(true);
   m_Controls.StepBMode->setEnabled(true);
 
   UpdateSaveBoxes();
 
   m_Controls.DoResampling->setEnabled(true);
   UseResampling();
   m_Controls.Logfilter->setEnabled(true);
   m_Controls.BModeMethod->setEnabled(true);
   m_Controls.buttonApplyBModeFilter->setEnabled(true);
 
   m_Controls.CutoffAbove->setEnabled(true);
   m_Controls.CutoffBelow->setEnabled(true);
   m_Controls.buttonApplyCropFilter->setEnabled(true);
   m_Controls.BPSpeedOfSound->setEnabled(true);
   m_Controls.buttonApplyBandpass->setEnabled(true);
 
   m_Controls.Partial->setEnabled(true);
   m_Controls.boundHigh->setEnabled(true);
   m_Controls.boundLow->setEnabled(true);
   m_Controls.BFAlgorithm->setEnabled(true);
   m_Controls.DelayCalculation->setEnabled(true);
   m_Controls.ImageType->setEnabled(true);
   m_Controls.Apodization->setEnabled(true);
   m_Controls.UseBP->setEnabled(true);
 
 #ifdef PHOTOACOUSTICS_USE_GPU
   m_Controls.UseGPUBf->setEnabled(true);
   m_Controls.UseGPUBmode->setEnabled(true);
 #endif
 
   m_Controls.BPhigh->setEnabled(true);
   m_Controls.BPlow->setEnabled(true);
   m_Controls.BPFalloffLow->setEnabled(true);
   m_Controls.BPFalloffHigh->setEnabled(true);
   m_Controls.UseImageSpacing->setEnabled(true);
   UseImageSpacing();
   m_Controls.Pitch->setEnabled(true);
   m_Controls.ElementCount->setEnabled(true);
   m_Controls.SpeedOfSound->setEnabled(true);
   m_Controls.Samples->setEnabled(true);
   m_Controls.Lines->setEnabled(true);
   m_Controls.Angle->setEnabled(true);
   m_Controls.buttonApplyBeamforming->setEnabled(true);
 }
 
 void PAImageProcessing::DisableControls()
 {
   m_Controls.BatchProcessing->setEnabled(false);
   m_Controls.StepBeamforming->setEnabled(false);
   m_Controls.StepBandpass->setEnabled(false);
   m_Controls.StepCropping->setEnabled(false);
   m_Controls.StepBMode->setEnabled(false);
   m_Controls.SaveBeamforming->setEnabled(false);
   m_Controls.SaveBandpass->setEnabled(false);
   m_Controls.SaveCropping->setEnabled(false);
   m_Controls.SaveBMode->setEnabled(false);
 
   m_Controls.DoResampling->setEnabled(false);
   m_Controls.ResamplingValue->setEnabled(false);
   m_Controls.Logfilter->setEnabled(false);
   m_Controls.BModeMethod->setEnabled(false);
   m_Controls.buttonApplyBModeFilter->setEnabled(false);
 
   m_Controls.CutoffAbove->setEnabled(false);
   m_Controls.CutoffBelow->setEnabled(false);
   m_Controls.buttonApplyCropFilter->setEnabled(false);
   m_Controls.BPSpeedOfSound->setEnabled(false);
   m_Controls.buttonApplyBandpass->setEnabled(false);
 
   m_Controls.Partial->setEnabled(false);
   m_Controls.boundHigh->setEnabled(false);
   m_Controls.boundLow->setEnabled(false);
   m_Controls.BFAlgorithm->setEnabled(false);
   m_Controls.DelayCalculation->setEnabled(false);
   m_Controls.ImageType->setEnabled(false);
   m_Controls.Apodization->setEnabled(false);
   m_Controls.UseBP->setEnabled(false);
 
 #ifdef PHOTOACOUSTICS_USE_GPU
   m_Controls.UseGPUBf->setEnabled(false);
   m_Controls.UseGPUBmode->setEnabled(false);
 #endif
 
   m_Controls.BPhigh->setEnabled(false);
   m_Controls.BPlow->setEnabled(false);
   m_Controls.BPFalloffLow->setEnabled(false);
   m_Controls.BPFalloffHigh->setEnabled(false);
   m_Controls.UseImageSpacing->setEnabled(false);
   m_Controls.ScanDepth->setEnabled(false);
   m_Controls.Pitch->setEnabled(false);
   m_Controls.ElementCount->setEnabled(false);
   m_Controls.SpeedOfSound->setEnabled(false);
   m_Controls.Samples->setEnabled(false);
   m_Controls.Lines->setEnabled(false);
   m_Controls.Angle->setEnabled(false);
   m_Controls.buttonApplyBeamforming->setEnabled(false);
 }
 
 void PAImageProcessing::UseImageSpacing()
 {
   if (m_Controls.UseImageSpacing->isChecked())
   {
     m_Controls.ScanDepth->setDisabled(true);
   }
   else
   {
     m_Controls.ScanDepth->setEnabled(true);
   }
 }
 
 #include <mitkImageReadAccessor.h>
 
 void BeamformingThread::run()
 {
   mitk::Image::Pointer resultImage = mitk::Image::New();
   mitk::Image::Pointer resultImageBuffer;
   std::string errorMessage = "";
   std::function<void(int, std::string)> progressHandle = [this](int progress, std::string progressInfo) {
     emit updateProgress(progress, progressInfo);
   };
 
   resultImageBuffer = m_FilterBank->ApplyBeamforming(m_InputImage, m_BFconfig, errorMessage, progressHandle);
   mitk::ImageReadAccessor copy(resultImageBuffer);
 
   resultImage->Initialize(resultImageBuffer);
   resultImage->SetSpacing(resultImageBuffer->GetGeometry()->GetSpacing());
   resultImage->SetImportVolume(const_cast<void*>(copy.GetData()), 0, 0, mitk::Image::CopyMemory);
 
   emit result(resultImage);
   emit message(errorMessage);
 }
 
 void BeamformingThread::setConfig(mitk::BeamformingSettings::Pointer BFconfig)
 {
   m_BFconfig = BFconfig;
 }
 
 void BeamformingThread::setInputImage(mitk::Image::Pointer image)
 {
   m_InputImage = image;
 }
 
 void BmodeThread::run()
 {
   mitk::Image::Pointer resultImage;
 
   resultImage = m_FilterBank->ApplyBmodeFilter(m_InputImage, m_Method, m_UseGPU, m_UseLogfilter, m_ResampleSpacing);
 
   emit result(resultImage);
 }
 
 void BmodeThread::setConfig(bool useLogfilter, double resampleSpacing, mitk::PhotoacousticFilterService::BModeMethod method, bool useGPU)
 {
   m_UseLogfilter = useLogfilter;
   m_ResampleSpacing = resampleSpacing;
   m_Method = method;
   m_UseGPU = useGPU;
 }
 
 void BmodeThread::setInputImage(mitk::Image::Pointer image)
 {
   m_InputImage = image;
 }
 
 void CropThread::run()
 {
   mitk::Image::Pointer resultImage;
 
-  resultImage = m_FilterBank->ApplyCropping(m_InputImage, m_CutAbove, m_CutBelow, 0, 0, m_CutSliceFirst, m_CutSliceLast);
+  resultImage = m_FilterBank->ApplyCropping(m_InputImage, m_CutAbove, m_CutBelow, 0, 0, 0, 0);
 
   emit result(resultImage);
 }
 
 void CropThread::setConfig(unsigned int CutAbove, unsigned int CutBelow, unsigned int CutSliceFirst, unsigned int CutSliceLast)
 {
   m_CutAbove = CutAbove;
   m_CutBelow = CutBelow;
   m_CutSliceLast = CutSliceLast;
   m_CutSliceFirst = CutSliceFirst;
 }
 
 void CropThread::setInputImage(mitk::Image::Pointer image)
 {
   m_InputImage = image;
 }
 
 void BandpassThread::run()
 {
   mitk::Image::Pointer resultImage;
 
   resultImage = m_FilterBank->BandpassFilter(m_InputImage, m_RecordTime, m_BPHighPass, m_BPLowPass, m_TukeyAlphaHighPass, m_TukeyAlphaLowPass);
   emit result(resultImage);
 }
 
 void BandpassThread::setConfig(float BPHighPass, float BPLowPass, float TukeyAlphaHighPass, float TukeyAlphaLowPass, float recordTime)
 {
   m_BPHighPass = BPHighPass;
   m_BPLowPass = BPLowPass;
   m_TukeyAlphaHighPass = TukeyAlphaHighPass;
   m_TukeyAlphaLowPass = TukeyAlphaLowPass;
   m_RecordTime = recordTime;
 }
 
 void BandpassThread::setInputImage(mitk::Image::Pointer image)
 {
   m_InputImage = image;
 }