void udgPerfusionEstimator<TPerfuImage,TMaskImage, TTransform>::ComputeEstimation() { if(m_perfuImage.IsNull()){ std::cout<<"Not Perfusion Image defined"<<std::endl; return; } if(m_ventricleMask.IsNull()){ std::cout<<"Not Ventricle Mask Image defined"<<std::endl; return; } if(m_strokeMask.IsNull()){ std::cout<<"Not Stroke Mask Image defined"<<std::endl; return; } if(m_Transform.IsNull()){ std::cout<<"Not Transform defined"<<std::endl; return; } m_estimatedImage = PerfuImageType::New(); m_estimatedImage->SetRegions( m_perfuImage->GetLargestPossibleRegion() ); m_estimatedImage->SetSpacing( m_perfuImage->GetSpacing() ); m_estimatedImage->SetOrigin( m_perfuImage->GetOrigin() ); m_estimatedImage->Allocate(); //Definim la regi�molt probablement infartada typename MaskImageType::Pointer m_strokeInfluence = MaskImageType::New(); m_strokeInfluence->SetRegions( m_strokeMask->GetLargestPossibleRegion() ); m_strokeInfluence->SetSpacing( m_strokeMask->GetSpacing() ); m_strokeInfluence->SetOrigin( m_strokeMask->GetOrigin() ); m_strokeInfluence->Allocate(); typename DilateFilterType::Pointer binaryDilate = DilateFilterType::New(); binaryDilate->SetDilateValue( 255 ); //suposem que el valor alt ser�255 StructuringElementType structuringElementDilate; structuringElementDilate.SetRadius( 2 ); // 3x3 structuring element structuringElementDilate.CreateStructuringElement(); binaryDilate->SetKernel( structuringElementDilate ); binaryDilate->SetInput( m_strokeMask ); binaryDilate->Update(); m_strokeInfluence = binaryDilate->GetOutput(); //Fi regi�molt probablement infartada typename ResampleFilterType::Pointer resample = ResampleFilterType::New(); typename TransformType::Pointer inverse = TransformType::New(); if (!m_Transform->GetInverse( inverse )) { std::cout<<"ERROR! udgPerfusionEstimator<TPerfuImage,TMaskImage, TTransform>::ComputeEstimation() No hi ha inversa!"<<std::endl; } resample->SetTransform( inverse ); resample->SetInput( m_ventricleMask); resample->SetSize( m_perfuImage->GetLargestPossibleRegion().GetSize() ); resample->SetOutputOrigin( m_perfuImage->GetOrigin() ); resample->SetOutputSpacing( m_perfuImage->GetSpacing() ); resample->SetDefaultPixelValue( 0 ); resample->SetInterpolator( m_InterpolatorVentricle ); resample->Update(); Ventricles = resample->GetOutput(); typename ResampleFilterType::Pointer resample2 = ResampleFilterType::New(); resample2->SetTransform( inverse ); resample2->SetInput( m_strokeInfluence); resample2->SetSize( m_perfuImage->GetLargestPossibleRegion().GetSize() ); resample2->SetOutputOrigin( m_perfuImage->GetOrigin() ); resample2->SetOutputSpacing( m_perfuImage->GetSpacing() ); resample2->SetDefaultPixelValue( 0 ); resample2->SetInterpolator( m_InterpolatorStroke ); resample2->Update(); //Creem les finestres mostrant les imatges registrades Stroke = resample2->GetOutput(); PerfuIteratorType estimatedIt(m_estimatedImage, m_estimatedImage->GetBufferedRegion()); PerfuIteratorType perfuIt(m_perfuImage, m_perfuImage->GetBufferedRegion()); PerfuIteratorType VentIt(Ventricles, Ventricles->GetBufferedRegion()); PerfuIteratorType StkIt(Stroke, Stroke->GetBufferedRegion()); RadiusNeighborType radius; radius.Fill(2); m_InterpolatorVentricle->SetInputImage( m_ventricleMask ); m_InterpolatorStroke->SetInputImage( m_strokeInfluence ); PerfuPointType inputPoint; PerfuPixelType perfuValue; PerfuPixelType VentValue; PerfuPixelType StkValue; typename PerfuImageType::IndexType index; MaskPointType transformedPoint; perfuIt.GoToBegin(); VentIt.GoToBegin(); StkIt.GoToBegin(); estimatedIt.GoToBegin(); ++perfuIt; ++VentIt; ++StkIt; ++estimatedIt; while (!perfuIt.IsAtEnd()) { perfuValue = perfuIt.Value(); // if(perfuValue == 0) // ((maskValue == m_insideValue)&&(perfuValue == 0)) if ( perfuValue < 32 ) // ((maskValue == m_insideValue)&&(perfuValue == 0)) { //és a dir, és un punt negre index = perfuIt.GetIndex(); m_perfuImage->TransformIndexToPhysicalPoint(index, inputPoint); transformedPoint = m_Transform->TransformPoint(inputPoint); //transformed point és el punt corresponent en difusió if (m_InterpolatorVentricle->IsInsideBuffer(transformedPoint)) { // m_Interpolator->SetInputImage( m_ventricleMask ); //const RealType VentriclemaskValue = m_InterpolatorVentricle->Evaluate(transformedPoint); VentValue = VentIt.Value(); // if(VentriclemaskValue!=0) if(VentValue!=0) { estimatedIt.Set(0);//estimatedIt.Set(1); } else { /* const RealType strokemaskValue = m_InterpolatorStroke->Evaluate(transformedPoint); if(strokemaskValue!=0){ estimatedIt.Set(1);//estimatedIt.Set(255); } */ StkValue = StkIt.Value(); if(StkValue != 0) { estimatedIt.Set(255); } else { estimatedIt.Set(0); } } } } else { estimatedIt.Set( perfuValue ); //estimatedIt.Set( perfuValue ); } ++perfuIt; ++VentIt; ++StkIt; ++estimatedIt; } //Aqu�determinem els punts que no s� ni infart ni ventricle, fent una mitjana dels valors veins //La imatge s'actualitza sobre ella mateixa, per�no sembla que aix�hagi de portar problemes /* double med, cont; PerfuNeighborIteratorType perfuNeighborIt(radius, m_estimatedImage, m_estimatedImage->GetBufferedRegion()); perfuNeighborIt.GoToBegin(); perfuIt.GoToBegin(); estimatedIt.GoToBegin(); ++perfuNeighborIt; ++estimatedIt; while (!estimatedIt.IsAtEnd()) { perfuValue = estimatedIt.Get(); if (perfuValue == 0) //� a dir, � un punt negre { med=0; cont=0; for (unsigned int i = 0; i < perfuNeighborIt.Size(); i++) { if ( perfuNeighborIt.GetPixel(i) != 0 && perfuNeighborIt.GetPixel(i)<1000 ) { med += perfuNeighborIt.GetPixel(i); cont ++; } } estimatedIt.Set(static_cast<PerfuPixelType> (med/cont)); } ++perfuNeighborIt; ++estimatedIt; } */ //Suavitzem la sortida --> S'hauria de fer per�d�a errors /* typename SmoothingFilterType::Pointer smoothFilter = SmoothingFilterType::New(); // smoothFilter->SetInput(m_estimatedImage); smoothFilter->SetInput(m_perfuImage); // smoothFilter->SetNumberOfIterations(5); // smoothFilter->SetTimeStep(0.0625); // smoothFilter->SetConductanceParameter(1); //std::cout<<"hola 1"<<std::endl; smoothFilter->SetVariance(1); smoothFilter->SetMaximumKernelWidth(6); //smoothFilter->Update(); RescaleFilterType::Pointer rescaler = RescaleFilterType::New(); rescaler->SetOutputMinimum( 0 ); rescaler->SetOutputMaximum( 255 ); //std::cout<<"hola 2"<<std::endl; rescaler->SetInput(smoothFilter->GetOutput()); rescaler->Update(); //std::cout<<"hola 3"<<std::endl; m_estimatedImage = rescaler->GetOutput(); */ }
static int CalculateGlSZMatrix(itk::Image<TPixel, VImageDimension>* itkImage, itk::Image<unsigned short, VImageDimension>* mask, std::vector<itk::Offset<VImageDimension> > offsets, bool estimateLargestRegion, mitk::GreyLevelSizeZoneMatrixHolder &holder) { typedef itk::Image<TPixel, VImageDimension> ImageType; typedef itk::Image<unsigned short, VImageDimension> MaskImageType; typedef typename ImageType::IndexType IndexType; typedef itk::ImageRegionIteratorWithIndex<ImageType> ConstIterType; typedef itk::ImageRegionIteratorWithIndex<MaskImageType> ConstMaskIterType; auto region = mask->GetLargestPossibleRegion(); typename MaskImageType::RegionType newRegion; newRegion.SetSize(region.GetSize()); newRegion.SetIndex(region.GetIndex()); ConstIterType imageIter(itkImage, itkImage->GetLargestPossibleRegion()); ConstMaskIterType maskIter(mask, mask->GetLargestPossibleRegion()); typename MaskImageType::Pointer visitedImage = MaskImageType::New(); visitedImage->SetRegions(newRegion); visitedImage->Allocate(); visitedImage->FillBuffer(0); int largestRegion = 0; while (!maskIter.IsAtEnd()) { if (maskIter.Value() > 0 ) { auto startIntensityIndex = holder.IntensityToIndex(imageIter.Value()); std::vector<IndexType> indices; indices.push_back(maskIter.GetIndex()); unsigned int steps = 0; while (indices.size() > 0) { auto currentIndex = indices.back(); indices.pop_back(); if (!region.IsInside(currentIndex)) { continue; } auto wasVisited = visitedImage->GetPixel(currentIndex); auto newIntensityIndex = holder.IntensityToIndex(itkImage->GetPixel(currentIndex)); auto isInMask = mask->GetPixel(currentIndex); if ((isInMask > 0) && (newIntensityIndex == startIntensityIndex) && (wasVisited < 1)) { ++steps; visitedImage->SetPixel(currentIndex, 1); for (auto offset : offsets) { auto newIndex = currentIndex + offset; indices.push_back(newIndex); newIndex = currentIndex - offset; indices.push_back(newIndex); } } } if (steps > 0) { largestRegion = std::max<int>(steps, largestRegion); steps = std::min<unsigned int>(steps, holder.m_MaximumSize); if (!estimateLargestRegion) { holder.m_Matrix(startIntensityIndex, steps - 1) += 1; } } } ++imageIter; ++maskIter; } return largestRegion; }
void PartialVolumeAnalysisClusteringCalculator::InternalQuantify( const itk::Image< TPixel, VImageDimension > *image, mitk::Image::Pointer clusteredImage, double* retval, mitk::Image::Pointer mask ) const { typedef itk::Image< TPixel, VImageDimension > ImageType; typedef itk::Image< float, VImageDimension > ProbImageType; typedef itk::Image< unsigned char, VImageDimension > MaskImageType; typedef mitk::ImageToItk<ProbImageType> CastFilterType; typename CastFilterType::Pointer castFilter = CastFilterType::New(); castFilter->SetInput( clusteredImage ); castFilter->Update(); typename ProbImageType::Pointer clusterImage = castFilter->GetOutput(); typename MaskImageType::Pointer itkmask = 0; if(mask.IsNotNull()) { typedef mitk::ImageToItk<MaskImageType> CastFilterType2; typename CastFilterType2::Pointer castFilter2 = CastFilterType2::New(); castFilter2->SetInput( mask ); castFilter2->Update(); itkmask = castFilter2->GetOutput(); } else { itkmask = MaskImageType::New(); itkmask->SetSpacing( clusterImage->GetSpacing() ); // Set the image spacing itkmask->SetOrigin( clusterImage->GetOrigin() ); // Set the image origin itkmask->SetDirection( clusterImage->GetDirection() ); // Set the image direction itkmask->SetRegions( clusterImage->GetLargestPossibleRegion() ); itkmask->Allocate(); itkmask->FillBuffer(1); } itk::ImageRegionConstIterator<ImageType> itimage(image, image->GetLargestPossibleRegion()); itk::ImageRegionConstIterator<ProbImageType> itprob(clusterImage, clusterImage->GetLargestPossibleRegion()); itk::ImageRegionConstIterator<MaskImageType> itmask(itkmask, itkmask->GetLargestPossibleRegion()); itimage.GoToBegin(); itprob.GoToBegin(); itmask.GoToBegin(); double totalProb = 0; double measurement = 0; double error = 0; while( !itimage.IsAtEnd() && !itprob.IsAtEnd() && !itmask.IsAtEnd() ) { double valImag = itimage.Get(); double valProb = itprob.Get(); double valMask = itmask.Get(); typename ProbImageType::PixelType prop = valProb * valMask; totalProb += prop; measurement += valImag * prop; error += valImag * valImag * prop; ++itimage; ++itprob; ++itmask; } measurement = measurement / totalProb; error = error / totalProb; retval[0] = measurement; retval[1] = sqrt( error - measurement*measurement ); }