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I would like to take two images and convolve them together in Matlab using the 2D FFT without recourse to the conv2 function. However, I am uncertain with respect to how the matrices should be properly padded and prepared for the convolution.

The mathematical operation is the following:

A * B = C

In the above, * is the convolution operator (Wikipedia link).

The following Matlab program shows the difference between padding and not padding the matrices. I suspect that not padding the matrices results in a circular convolution, but I would like to perform a linear convolution without aliasing.

If I do pad the two matrices, then how do I truncate the output of the convolution so that C is the same size as A and B?

A = rgb2gray(im2double(imread('1.png'))); % input A
B = rgb2gray(im2double(imread('2.png'))); % kernel B

imagesc(A); colormap gray;
title ('A')

imagesc(B); colormap gray;
title ('B')

[m,n] = size(A);
mm = 2*m - 1;
nn = 2*n - 1;

C = (ifft2(fft2(A,mm,nn).* fft2(B,mm,nn)));

imagesc(C); colormap gray;
title ('C with padding')

C0 = (ifft2(fft2(A).* fft2(B)));

imagesc(C0); colormap gray;
title ('C without padding')

Here is the output of the program:

A B C C0

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1 Answer 1

up vote 8 down vote accepted

Without padding the result will be equivalent to circular convolution as you point out. For linear convolution, in convolving 2 images (2D signals) A*B the full output will be of size Ma+Mb-1 x Na+Nb-1, where Ma x Na, Mb x Nb the sizes of images A and B resp.

After padding to the expected size, multiplying and transforming back, via ifft2, you can keep the central part of the resulting image (usually corresponding to the largest one of A and B).

A = double(imread('cameraman.tif'))./255; % image
B = fspecial('gaussian', [15 15], 2); % some 2D filter function

[m,n] = size(A);
[mb,nb] = size(B); 
% output size 
mm = m + mb - 1;
nn = n + nb - 1;

% pad, multiply and transform back
C = ifft2(fft2(A,mm,nn).* fft2(B,mm,nn));

% padding constants (for output of size == size(A))
padC_m = ceil((mb-1)./2);
padC_n = ceil((nb-1)./2);

% frequency-domain convolution result
D = C(padC_m+1:m+padC_m, padC_n+1:n+padC_n); 
figure; imshow(D,[]);

Now, compare the above with doing spatial-domain convolution, using conv2D

 % space-domain convolution result
 F = conv2(A,B,'same');
 figure; imshow(F,[]);

Results are visually the same, and total error between the two (due to rounding) on the order of e-10.

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This is just wonderful, gevang. Thank you so much for such a complete answer! A question: Since the convolution operation is related to correlation, would I do the same for the 2D correlation of the two matrices? Would ifft2(fft2(M1,mm,nn).*fft2(fliplr(flipud(M2))),mm,nn) be the Matlab code for the correlation, and then I would keep the central part of the image in the same manner as shown in your answer above? –  Nicholas Kinar Sep 3 '12 at 22:57
In addition, if A and B were complex matrices, would the convolution (or correlation) operation code work in exactly the same way? –  Nicholas Kinar Sep 3 '12 at 23:01
Since convolution (and Fourier transform) are linear operations and distributive with addition, the equivalence will hold for signals of the form A + Aj, i.e. you will have a sum of convolutions between combinations of the real and imaginary parts of images of the original size. You can check by replacing A and B with complex matrices above. If both are complex, visualize the abs() of the output or compare the difference between the real() and imag() parts of F and D. –  gevang Sep 3 '12 at 23:23
Thanks again, gevang. Yes, after some experimentation, I can confirm that the convolution code works in Matlab for signals of the form A + Aj. –  Nicholas Kinar Sep 4 '12 at 0:20
Moreover, using the Matlab xcorr2 function as a much-slower test, it appears that the 2D correlation of the A and B matrices can be computed by ifft2(fft2(A,mm,nn).*fft2(fliplr(flipud(B)),mm,nn)); or equivalently ifft2(fft2(A,mm,nn).*fft2(rot90(B,2),mm,nn)). A reference for this is the DSP book by Steven Smith: dspguide.com/ch24/6.htm. –  Nicholas Kinar Sep 4 '12 at 0:27

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