My task is noise removal from an image using opencv

  • Step1 : load an image with noise
  • Step2 : using discrete fourier transformation to see where the frequencies are, that should be removed
  • Step3 : create a custom filter and multiply fourier spectrum with that filter pixel by pixel to eliminate noise
  • Step4 : inverse discrete fourier transformation to get the original image without noise

For step2 I am using this function provided by opencv doc:

void fourier_transform(const Mat& I, Mat& dst) {
 Mat padded;                            //expand input image to optimal size
 int m = getOptimalDFTSize( I.rows );
 int n = getOptimalDFTSize( I.cols ); // on the border add zero values
 copyMakeBorder(I, padded, 0, m - I.rows, 0, n - I.cols, BORDER_CONSTANT, Scalar::all(0));
 Mat planes[2] = {Mat_<float>(padded), Mat::zeros(padded.size(), CV_32F)};
 Mat complexI;
 merge(planes, 2, complexI);         // Add to the expanded another plane with zeros

 dft(complexI, complexI);            // this way the result may fit in the source matrix

 // compute the magnitude and switch to logarithmic scale
 // => log(1 + sqrt(Re(DFT(I))^2 + Im(DFT(I))^2))
 split(complexI, planes);                   // planes[0] = Re(DFT(I), planes[1] = Im(DFT(I))
 magnitude(planes[0], planes[1], planes[0]);// planes[0] = magnitude
 Mat magI = planes[0];

 magI += Scalar::all(1);                    // switch to logarithmic scale
 log(magI, magI);

 // crop the spectrum, if it has an odd number of rows or columns
 magI = magI(Rect(0, 0, magI.cols & -2, magI.rows & -2));

 // rearrange the quadrants of Fourier image  so that the origin is at the image center
 int cx = magI.cols/2;
 int cy = magI.rows/2;

 Mat q0(magI, Rect(0, 0, cx, cy));   // Top-Left - Create a ROI per quadrant
 Mat q1(magI, Rect(cx, 0, cx, cy));  // Top-Right
 Mat q2(magI, Rect(0, cy, cx, cy));  // Bottom-Left
 Mat q3(magI, Rect(cx, cy, cx, cy)); // Bottom-Right

 Mat tmp;                           // swap quadrants (Top-Left with Bottom-Right)
 q0.copyTo(tmp);
 q3.copyTo(q0);
 tmp.copyTo(q3);

 q1.copyTo(tmp);                    // swap quadrant (Top-Right with Bottom-Left)
 q2.copyTo(q1);
 tmp.copyTo(q2);

 normalize(magI, magI, 0, 1, NORM_MINMAX); // Transform the matrix with float values into a
                                         // viewable image form (float between values 0 and 1).
 dst = magI.clone();
}

For step3 I am using the shifted logarithmic image ("dst" at the very bottom of the fourier_transform function) to multiply it with my filter image. Now for step4 I want to do something like this:

void inverse_fourier_transform(Mat& src, Mat& dst) {
   // stuff to do?
   idft(src, dst);
   imshow(dst);
}

src = fouriertransformed image * filter

When I try to run this code, I just get a black image as a result. The problem might be that "src" is still in log-scale and the quadrants are switched as you can see in the fourier_transform function, but I dont know how to handle this issue. Can you tell me what to do before I can use idft() ?

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