void CalculateFirstOrderStatistics(itk::Image<TPixel, VImageDimension>* itkImage, mitk::Image::Pointer mask, mitk::GIFFirstOrderStatistics::FeatureListType & featureList) { typedef itk::Image<TPixel, VImageDimension> ImageType; typedef itk::Image<int, VImageDimension> MaskType; typedef itk::LabelStatisticsImageFilter<ImageType, MaskType> FilterType; typedef typename FilterType::HistogramType HistogramType; typedef typename HistogramType::IndexType HIndexType; typedef itk::MinimumMaximumImageCalculator<ImageType> MinMaxComputerType; typename MaskType::Pointer maskImage = MaskType::New(); mitk::CastToItkImage(mask, maskImage); typename MinMaxComputerType::Pointer minMaxComputer = MinMaxComputerType::New(); minMaxComputer->SetImage(itkImage); minMaxComputer->Compute(); double imageRange = minMaxComputer->GetMaximum() - minMaxComputer->GetMinimum(); typename FilterType::Pointer labelStatisticsImageFilter = FilterType::New(); labelStatisticsImageFilter->SetInput( itkImage ); labelStatisticsImageFilter->SetLabelInput(maskImage); labelStatisticsImageFilter->SetUseHistograms(true); labelStatisticsImageFilter->SetHistogramParameters(256, minMaxComputer->GetMinimum(),minMaxComputer->GetMaximum()); labelStatisticsImageFilter->Update(); // --------------- Range -------------------- double range = labelStatisticsImageFilter->GetMaximum(1) - labelStatisticsImageFilter->GetMinimum(1); // --------------- Uniformity, Entropy -------------------- double count = labelStatisticsImageFilter->GetCount(1); double std_dev = labelStatisticsImageFilter->GetSigma(1); double mean = labelStatisticsImageFilter->GetMean(1); auto histogram = labelStatisticsImageFilter->GetHistogram(1); HIndexType index; index.SetSize(1); double binWidth = histogram->GetBinMax(0, 0) - histogram->GetBinMin(0, 0); double uniformity = 0; double entropy = 0; double squared_sum = 0; double kurtosis = 0; double mean_absolut_deviation = 0; double skewness = 0; for (int i = 0; i < (int)(histogram->GetSize(0)); ++i) { index[0] = i; double prob = histogram->GetFrequency(index); double voxelValue = histogram->GetBinMin(0, i) +binWidth * 0.5; squared_sum += prob * voxelValue*voxelValue; kurtosis += prob* (voxelValue - mean) * (voxelValue - mean) * (voxelValue - mean) * (voxelValue - mean); skewness += prob* (voxelValue - mean) * (voxelValue - mean) * (voxelValue - mean); mean_absolut_deviation = prob* std::abs(voxelValue - mean); prob /= count; uniformity += prob*prob; if (prob > 0) entropy += prob * std::log(prob); } double rms = std::sqrt(squared_sum / count); kurtosis = kurtosis / count / (std_dev * std_dev); skewness = skewness / count / (std_dev * std_dev * std_dev); mean_absolut_deviation = mean_absolut_deviation / count; double coveredGrayValueRange = range / imageRange; featureList.push_back(std::make_pair("FirstOrder Range",range)); featureList.push_back(std::make_pair("FirstOrder Uniformity",uniformity)); featureList.push_back(std::make_pair("FirstOrder Entropy",entropy)); featureList.push_back(std::make_pair("FirstOrder Energy",squared_sum)); featureList.push_back(std::make_pair("FirstOrder RMS",rms)); featureList.push_back(std::make_pair("FirstOrder Kurtosis",kurtosis)); featureList.push_back(std::make_pair("FirstOrder Skewness",skewness)); featureList.push_back(std::make_pair("FirstOrder Mean absolute deviation",mean_absolut_deviation)); featureList.push_back(std::make_pair("FirstOrder Covered Image Intensity Range",coveredGrayValueRange)); featureList.push_back(std::make_pair("FirstOrder Minimum",labelStatisticsImageFilter->GetMinimum(1))); featureList.push_back(std::make_pair("FirstOrder Maximum ",labelStatisticsImageFilter->GetMaximum(1))); featureList.push_back(std::make_pair("FirstOrder Mean",labelStatisticsImageFilter->GetMean(1))); featureList.push_back(std::make_pair("FirstOrder Variance",labelStatisticsImageFilter->GetVariance(1))); featureList.push_back(std::make_pair("FirstOrder Sum",labelStatisticsImageFilter->GetSum(1))); featureList.push_back(std::make_pair("FirstOrder Median",labelStatisticsImageFilter->GetMedian(1))); featureList.push_back(std::make_pair("FirstOrder Standard deviation",labelStatisticsImageFilter->GetSigma(1))); featureList.push_back(std::make_pair("FirstOrder No. of Voxel",labelStatisticsImageFilter->GetCount(1))); }
void CalculateFirstOrderStatistics(itk::Image<TPixel, VImageDimension>* itkImage, mitk::Image::Pointer mask, mitk::GIFFirstOrderStatistics::FeatureListType & featureList, mitk::GIFFirstOrderStatistics::ParameterStruct params) { typedef itk::Image<TPixel, VImageDimension> ImageType; typedef itk::Image<unsigned short, VImageDimension> MaskType; typedef itk::LabelStatisticsImageFilter<ImageType, MaskType> FilterType; typedef typename FilterType::HistogramType HistogramType; typedef typename HistogramType::IndexType HIndexType; typedef itk::MinimumMaximumImageCalculator<ImageType> MinMaxComputerType; typename MaskType::Pointer maskImage = MaskType::New(); mitk::CastToItkImage(mask, maskImage); double voxelVolume = 1; for (unsigned int i = 0; i < std::min<unsigned int>(3, VImageDimension); ++i) voxelVolume *= itkImage->GetSpacing()[i]; double voxelSpace = 1; for (unsigned int i = 0; i < VImageDimension; ++i) voxelSpace *= itkImage->GetSpacing()[i]; typename MinMaxComputerType::Pointer minMaxComputer = MinMaxComputerType::New(); minMaxComputer->SetImage(itkImage); minMaxComputer->Compute(); double imageRange = minMaxComputer->GetMaximum() - minMaxComputer->GetMinimum(); typename FilterType::Pointer labelStatisticsImageFilter = FilterType::New(); labelStatisticsImageFilter->SetInput( itkImage ); labelStatisticsImageFilter->SetLabelInput(maskImage); labelStatisticsImageFilter->SetUseHistograms(true); double min = params.MinimumIntensity; double max = params.MaximumIntensity; labelStatisticsImageFilter->SetHistogramParameters(params.Bins, min,max); labelStatisticsImageFilter->Update(); // --------------- Range -------------------- double range = labelStatisticsImageFilter->GetMaximum(1) - labelStatisticsImageFilter->GetMinimum(1); // --------------- Uniformity, Entropy -------------------- double count = labelStatisticsImageFilter->GetCount(1); //double std_dev = labelStatisticsImageFilter->GetSigma(1); double mean = labelStatisticsImageFilter->GetMean(1); double median = labelStatisticsImageFilter->GetMedian(1); auto histogram = labelStatisticsImageFilter->GetHistogram(1); bool histogramIsCalculated = histogram; HIndexType index; index.SetSize(1); double uniformity = 0; double entropy = 0; double squared_sum = 0; double kurtosis = 0; double mean_absolut_deviation = 0; double median_absolut_deviation = 0; double skewness = 0; double sum_prob = 0; double binWidth = 0; double p05th = 0, p10th = 0, p15th = 0, p20th = 0, p25th = 0, p30th = 0, p35th = 0, p40th = 0, p45th = 0, p50th = 0; double p55th = 0, p60th = 0, p65th = 0, p70th = 0, p75th = 0, p80th = 0, p85th = 0, p90th = 0, p95th = 0; double voxelValue = 0; if (histogramIsCalculated) { binWidth = histogram->GetBinMax(0, 0) - histogram->GetBinMin(0, 0); p05th = histogram->Quantile(0, 0.05); p10th = histogram->Quantile(0, 0.10); p15th = histogram->Quantile(0, 0.15); p20th = histogram->Quantile(0, 0.20); p25th = histogram->Quantile(0, 0.25); p30th = histogram->Quantile(0, 0.30); p35th = histogram->Quantile(0, 0.35); p40th = histogram->Quantile(0, 0.40); p45th = histogram->Quantile(0, 0.45); p50th = histogram->Quantile(0, 0.50); p55th = histogram->Quantile(0, 0.55); p60th = histogram->Quantile(0, 0.60); p65th = histogram->Quantile(0, 0.65); p70th = histogram->Quantile(0, 0.70); p75th = histogram->Quantile(0, 0.75); p80th = histogram->Quantile(0, 0.80); p85th = histogram->Quantile(0, 0.85); p90th = histogram->Quantile(0, 0.90); p95th = histogram->Quantile(0, 0.95); } double Log2=log(2); double mode_bin; double mode_value = 0; double variance = 0; if (histogramIsCalculated) { for (int i = 0; i < (int)(histogram->GetSize(0)); ++i) { index[0] = i; double prob = histogram->GetFrequency(index); if (prob < 0.00000001) continue; voxelValue = histogram->GetBinMin(0, i) + binWidth * 0.5; if (prob > mode_value) { mode_value = prob; mode_bin = voxelValue; } sum_prob += prob; squared_sum += prob * voxelValue*voxelValue; prob /= count; mean_absolut_deviation += prob* std::abs(voxelValue - mean); median_absolut_deviation += prob* std::abs(voxelValue - median); variance += prob * (voxelValue - mean) * (voxelValue - mean); kurtosis += prob* (voxelValue - mean) * (voxelValue - mean) * (voxelValue - mean) * (voxelValue - mean); skewness += prob* (voxelValue - mean) * (voxelValue - mean) * (voxelValue - mean); uniformity += prob*prob; if (prob > 0) { entropy += prob * std::log(prob) / Log2; } } } entropy = -entropy; double uncorrected_std_dev = std::sqrt(variance); double rms = std::sqrt(squared_sum / count); kurtosis = kurtosis / (variance * variance); skewness = skewness / (variance * uncorrected_std_dev); double coveredGrayValueRange = range / imageRange; double coefficient_of_variation = (mean == 0) ? 0 : std::sqrt(variance) / mean; double quantile_coefficient_of_dispersion = (p75th - p25th) / (p75th + p25th); //Calculate the robust mean absolute deviation //First, set all frequencies to 0 that are <10th or >90th percentile double meanRobust = 0.0; double robustMeanAbsoluteDeviation = 0.0; if (histogramIsCalculated) { for (int i = 0; i < (int)(histogram->GetSize(0)); ++i) { index[0] = i; if (histogram->GetBinMax(0, i) < p10th) { histogram->SetFrequencyOfIndex(index, 0); } else if (histogram->GetBinMin(0, i) > p90th) { histogram->SetFrequencyOfIndex(index, 0); } } //Calculate the mean for (int i = 0; i < (int)(histogram->GetSize(0)); ++i) { index[0] = i; meanRobust += histogram->GetFrequency(index) * 0.5 * (histogram->GetBinMin(0, i) + histogram->GetBinMax(0, i)); } meanRobust = meanRobust / histogram->GetTotalFrequency(); for (int i = 0; i < (int)(histogram->GetSize(0)); ++i) { index[0] = i; robustMeanAbsoluteDeviation += std::abs(histogram->GetFrequency(index) * ((0.5 * (histogram->GetBinMin(0, i) + histogram->GetBinMax(0, i))) - meanRobust )); } robustMeanAbsoluteDeviation = robustMeanAbsoluteDeviation / histogram->GetTotalFrequency(); } featureList.push_back(std::make_pair(params.prefix + "Mean", labelStatisticsImageFilter->GetMean(1))); featureList.push_back(std::make_pair(params.prefix + "Unbiased Variance", labelStatisticsImageFilter->GetVariance(1))); //Siehe Definition von Unbiased Variance estimation. (Wird nicht durch n sondern durch n-1 normalisiert) featureList.push_back(std::make_pair(params.prefix + "Biased Variance", variance)); featureList.push_back(std::make_pair(params.prefix + "Skewness", skewness)); featureList.push_back(std::make_pair(params.prefix + "Kurtosis", kurtosis)); featureList.push_back(std::make_pair(params.prefix + "Median", labelStatisticsImageFilter->GetMedian(1))); featureList.push_back(std::make_pair(params.prefix + "Minimum", labelStatisticsImageFilter->GetMinimum(1))); featureList.push_back(std::make_pair(params.prefix + "Maximum", labelStatisticsImageFilter->GetMaximum(1))); featureList.push_back(std::make_pair(params.prefix + "Range", range)); featureList.push_back(std::make_pair(params.prefix + "Mean Absolute Deviation", mean_absolut_deviation)); featureList.push_back(std::make_pair(params.prefix + "Robust Mean Absolute Deviation", robustMeanAbsoluteDeviation)); featureList.push_back(std::make_pair(params.prefix + "Median Absolute Deviation", median_absolut_deviation)); featureList.push_back(std::make_pair(params.prefix + "Coefficient Of Variation", coefficient_of_variation)); featureList.push_back(std::make_pair(params.prefix + "Quantile Coefficient Of Dispersion", quantile_coefficient_of_dispersion)); featureList.push_back(std::make_pair(params.prefix + "Energy", squared_sum)); featureList.push_back(std::make_pair(params.prefix + "Root Mean Square", rms)); typename HistogramType::MeasurementVectorType mv(1); mv[0] = 0; typename HistogramType::IndexType resultingIndex; histogram->GetIndex(mv, resultingIndex); featureList.push_back(std::make_pair(params.prefix + "Robust Mean", meanRobust)); featureList.push_back(std::make_pair(params.prefix + "Uniformity", uniformity)); featureList.push_back(std::make_pair(params.prefix + "Entropy", entropy)); featureList.push_back(std::make_pair(params.prefix + "Excess Kurtosis", kurtosis - 3)); featureList.push_back(std::make_pair(params.prefix + "Covered Image Intensity Range", coveredGrayValueRange)); featureList.push_back(std::make_pair(params.prefix + "Sum", labelStatisticsImageFilter->GetSum(1))); featureList.push_back(std::make_pair(params.prefix + "Mode", mode_bin)); featureList.push_back(std::make_pair(params.prefix + "Mode Probability", mode_value)); featureList.push_back(std::make_pair(params.prefix + "Unbiased Standard deviation", labelStatisticsImageFilter->GetSigma(1))); featureList.push_back(std::make_pair(params.prefix + "Biased Standard deviation", sqrt(variance))); featureList.push_back(std::make_pair(params.prefix + "Number Of Voxels", labelStatisticsImageFilter->GetCount(1))); featureList.push_back(std::make_pair(params.prefix + "05th Percentile", p05th)); featureList.push_back(std::make_pair(params.prefix + "10th Percentile", p10th)); featureList.push_back(std::make_pair(params.prefix + "15th Percentile", p15th)); featureList.push_back(std::make_pair(params.prefix + "20th Percentile", p20th)); featureList.push_back(std::make_pair(params.prefix + "25th Percentile", p25th)); featureList.push_back(std::make_pair(params.prefix + "30th Percentile", p30th)); featureList.push_back(std::make_pair(params.prefix + "35th Percentile", p35th)); featureList.push_back(std::make_pair(params.prefix + "40th Percentile", p40th)); featureList.push_back(std::make_pair(params.prefix + "45th Percentile", p45th)); featureList.push_back(std::make_pair(params.prefix + "50th Percentile", p50th)); featureList.push_back(std::make_pair(params.prefix + "55th Percentile", p55th)); featureList.push_back(std::make_pair(params.prefix + "60th Percentile", p60th)); featureList.push_back(std::make_pair(params.prefix + "65th Percentile", p65th)); featureList.push_back(std::make_pair(params.prefix + "70th Percentile", p70th)); featureList.push_back(std::make_pair(params.prefix + "75th Percentile", p75th)); featureList.push_back(std::make_pair(params.prefix + "80th Percentile", p80th)); featureList.push_back(std::make_pair(params.prefix + "85th Percentile", p85th)); featureList.push_back(std::make_pair(params.prefix + "90th Percentile", p90th)); featureList.push_back(std::make_pair(params.prefix + "95th Percentile", p95th)); featureList.push_back(std::make_pair(params.prefix + "Interquartile Range", (p75th - p25th))); featureList.push_back(std::make_pair(params.prefix + "Image Dimension", VImageDimension)); featureList.push_back(std::make_pair(params.prefix + "Voxel Space", voxelSpace)); featureList.push_back(std::make_pair(params.prefix + "Voxel Volume", voxelVolume)); }