org.openimaj.image.processing.convolution.FDiscGausConvolve Maven / Gradle / Ivy
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* Copyright (c) 2011, The University of Southampton and the individual contributors.
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package org.openimaj.image.processing.convolution;
import org.openimaj.image.FImage;
import org.openimaj.image.processor.SinglebandImageProcessor;
import edu.emory.mathcs.jtransforms.fft.FloatFFT_2D;
/**
* From the matlab implementation of DISCGAUSSFFT which uses an FFT to apply a gaussian kernel.
* The matlab docs:
*
% DISCGAUSSFFT(pic, sigma2) -- Convolves an image by the
% (separable) discrete analogue of the Gaussian kernel by
% performing the convolution in the Fourier domain.
% The parameter SIGMA2 is the variance of the kernel.
% Reference: Lindeberg "Scale-space theory in computer vision", Kluwer, 1994.
*
* @author Sina Samangooei ([email protected])
*
*/
public class FDiscGausConvolve implements SinglebandImageProcessor {
private float sigma2;
/**
* Construct with given variance
* @param sigma2 variance of the kernel
*/
public FDiscGausConvolve(float sigma2) {
this.sigma2 = sigma2;
// this.fft = new FastFourierTransformer();
}
@Override
public void processImage(FImage image) {
int cs = image.getCols();
int rs = image.getRows();
FloatFFT_2D fft = new FloatFFT_2D(rs,cs);
float[][] prepared = new float[rs][cs*2];
for(int r = 0; r < rs ; r++){
for(int c = 0; c < cs; c++){
prepared[r][c*2] = image.pixels[r][c];
prepared[r][1 + c*2] = 0;
}
}
fft.complexForward(prepared);
for(int y = 0; y < rs; y++){
for(int x = 0; x < cs; x++){
double xcos = Math.cos(2 * Math.PI * ((float)x/cs));
double ycos = Math.cos(2 * Math.PI * ((float)y/rs));
float multiply = (float) Math.exp(sigma2 * (xcos + ycos - 2));
prepared[y][x*2] = prepared[y][x*2] * multiply;
prepared[y][1 + x*2] = prepared[y][1 + x*2] * multiply;
}
}
fft.complexInverse(prepared, true);
for(int r = 0; r < rs ; r++){
for(int c = 0; c < cs; c++){
image.pixels[r][c] = prepared[r][c*2];
}
}
}
}