protected Image<FloatType> getFloatImage() { if (floatImage == null) { ImageConverter<T, FloatType> convertToFloat = new ImageConverter<T, FloatType>( input, getFloatFactory(), new RealTypeConverter<T, FloatType>()); if (!convertToFloat.process()) return null; floatImage = convertToFloat.getResult(); } return floatImage; }
/** * Return a difference of gaussian image that measures the gradient at a scale defined by the two * sigmas of the gaussians. * * @param image * @param sigma1 * @param sigma2 * @return */ public Image<FloatType> getGradientImage() { /* * Create the DoG kernel. */ double[][] kernels1d1 = new double[input.getNumDimensions()][]; double[][] kernels1d2 = new double[input.getNumDimensions()][]; int[] kernelDimensions = input.createPositionArray(); int[] offset = input.createPositionArray(); for (int i = 0; i < kernels1d1.length; i++) { kernels1d1[i] = Util.createGaussianKernel1DDouble(sigma1[i], true); kernels1d2[i] = Util.createGaussianKernel1DDouble(sigma2[i], true); kernelDimensions[i] = kernels1d1[i].length; offset[i] = (kernels1d1[i].length - kernels1d2[i].length) / 2; } Image<FloatType> kernel = getFloatFactory().createImage(kernelDimensions); LocalizableCursor<FloatType> kc = kernel.createLocalizableCursor(); int[] position = input.createPositionArray(); for (FloatType t : kc) { kc.getPosition(position); double value1 = 1; double value2 = 1; for (int i = 0; i < kernels1d1.length; i++) { value1 *= kernels1d1[i][position[i]]; int position2 = position[i] - offset[i]; if ((position2 >= 0) && (position2 < kernels1d2[i].length)) { value2 *= kernels1d2[i][position2]; } else { value2 = 0; } } t.setReal(value1 - value2); } kc.close(); /* * Apply the kernel to the image. */ FourierConvolution<FloatType, FloatType> convolution = new FourierConvolution<FloatType, FloatType>(getFloatImage(), kernel); if (!convolution.process()) return null; Image<FloatType> result = convolution.getResult(); /* * Quantize the image. */ ComputeMinMax<FloatType> computeMinMax = new ComputeMinMax<FloatType>(result); computeMinMax.process(); final float min = computeMinMax.getMin().get(); final float max = computeMinMax.getMax().get(); if (max == min) return result; ImageConverter<FloatType, FloatType> quantizer = new ImageConverter<FloatType, FloatType>( result, result.getImageFactory(), new Converter<FloatType, FloatType>() { @Override public void convert(FloatType input, FloatType output) { float value = (input.get() - min) / (max - min); value = Math.round(value * 100); output.set(value); } }); quantizer.process(); return quantizer.getResult(); }