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Here's my attempt in implementing this lovely formula.


%WIGNER Computes Wigner-Distribution on an image (difference of two images).
function[wd] = wigner(difference)
%Image size
[M, N, ~] = size(difference);
%Window size (5 x 5)
Md = 5;
Nd = 5;
%Fourier Transform
F = fft2(difference);
%Initializing the wigner picture
wd = zeros(M, N, 'uint8');
lambda =0.02;
value = (4/(Md*Nd));
for x = 1+floor(Md/2):M - floor(Md/2)
    for y = 1+floor(Nd/2):N - floor(Nd/2)
        for l = -floor(Nd/2) : floor(Nd/2)
            for k = -floor(Md/2) : floor(Md/2)
                kernel = exp(-lambda * norm(k,l));
                kernel = kernel * value;
                theta = 4 * pi * ((real(F(x, y)) * (k/M) )+ (imag(F(x, y)) * (l/N)));
                wd(x, y) = (wd(x, y)) + (cos(theta) * difference(x + k, y + l) * difference(x - k, y - l) * (kernel));

As you can see, the outer two loops are for the sliding window, while the remaining inner ones are for the variables of the summation.

Now, my request for you my beloved stackoverflow users is: Can you help me improve these very nasty for loops that take more than its share of time, and turn it into vectorized loops? And will that improvement be of a significant change?

Thank you.

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I suppose you'll see an improvement for large values of M and N. How big are they? –  Eitan T May 25 '12 at 17:42
I can tell you vectorization will definitely improve computation speed. When MATLAB does vector math, it goes down all the way to your PC's BLAS for optimization. –  kevlar1818 May 25 '12 at 18:04
@EitanT The image dimensions are 320(N) x 240(M). –  Absi May 25 '12 at 18:24
I suggest you take a look at this question. –  Eitan T May 25 '12 at 18:30
@EitanT I looked at the link you posted. So far I converted all of the loops to meshgrids; but I've encountered a problem with the norm function. I want it to use the elements of the matrix instead of the matrix whole i.e. norm(K, L); where [L,K] = meshgrid(-floor(Nd/2):floor(Nd/2), -floor(Md/2):floor(Md/2)); –  Absi May 25 '12 at 21:08

2 Answers 2

up vote 0 down vote accepted

Those four nested loops are basically processing each pixel in the image in a sliding-neighborhood style. I immediately thought of NLFILTER and IM2COL functions.

Here is my attempt at vectorizing the code. Note that I haven't thoroughly tested it, or compared performance against loop-based solution:

function WD = wigner(D, Md, Nd, lambda)
    %# window size and lambda
    if nargin<2, Md = 5; end
    if nargin<3, Nd = 5; end
    if nargin<4, lambda = 5; end

    %# image size
    [M,N,~] = size(D);

    %# kernel = exp(-lambda*norm([k,l])
    [K,L] = meshgrid(-floor(Md/2):floor(Md/2), -floor(Nd/2):floor(Nd/2));
    K = K(:); L = L(:);
    kernel = exp(-lambda .* sqrt(K.^2+L.^2));

    %# frequency-domain part
    F = fft2(D);

    %# f(x+k,y+l) * f(x-k,y-l) * kernel
    C = im2col(D, [Md Nd], 'sliding');
    X1 = bsxfun(@times, C .* flipud(C), kernel);

    %# cos(theta)
    C = im2col(F, [Md Nd], 'sliding');
    C = C(round(Md*Nd/2),:);    %# take center pixels
    theta = bsxfun(@times, real(C), K/M) + bsxfun(@times, imag(C), L/N);
    X2 = cos(4*pi*theta);

    %# combine both parts for each sliding-neighborhood
    WD = col2im(sum(X1.*X2,1), [Md Nd], size(F), 'sliding') .* (4/(M*N));

    %# pad array with zeros to be of same size as input image
    WD = padarray(WD, ([Md Nd]-1)./2, 0, 'both');

For what its worth, here is the loop-based version with the improvement that @Laurbert515 suggested:

function WD = wigner_loop(D, Md, Nd, lambda)
    %# window size and lambda
    if nargin<2, Md = 5; end
    if nargin<3, Nd = 5; end
    if nargin<4, lambda = 5; end

    %# image size
    [M,N,~] = size(D);

    %# frequency-domain part
    F = fft2(D);

    WD = zeros([M,N]);
    for l = -floor(Nd/2):floor(Nd/2)
        for k = -floor(Md/2):floor(Md/2)
            %# kernel = exp(-lambda*norm([k,l])
            kernel = exp(-lambda * norm([k,l]));

            for x = (1+floor(Md/2)):(M-floor(Md/2))
                for y = (1+floor(Nd/2)):(N-floor(Nd/2))
                    %# cos(theta)
                    theta = 4 * pi * ( real(F(x,y))*k/M + imag(F(x,y))*l/N );

                    %# f(x+k,y+l) * f(x-k,y-l)* kernel
                    WD(x,y) = WD(x,y) + ( cos(theta) * D(x+k,y+l) * D(x-k,y-l) * kernel );
    WD = WD * ( 4/(M*N) );

and how I test it (based on what I understood from the paper you previously linked to):

%# difference between two consecutive frames
A = imread('AT3_1m4_02.tif');
B = imread('AT3_1m4_03.tif');
D = imsubtract(A,B);
%#D = rgb2gray(D);
D = im2double(D);

%# apply Wigner-Distribution
tic, WD1 = wigner(D); toc
tic, WD2 = wigner_loop(D); toc
figure(1), imshow(WD1,[])
figure(2), imshow(WD2,[])

you might then need to scale/normalize the matrix, and apply thresholding...

share|improve this answer
Hey Amro. First of all, thanks for the hard work. Second, I get this error when I run the function:- ??? Error using ==> reshape To RESHAPE the number of elements must not change. Error in ==> col2im at 84 a = reshape(b,mat(1)-block(1)+1,mat(2)-block(2)+1); Error in ==> wignerVector at 29 WD = col2im(sum(X1.*X2,1), [Md Nd], size(F), 'sliding') .* (4/(M*N));" –  Absi Jun 4 '12 at 22:31
@Absi: are you sure you are working with grayscale images? if not call RGB2GRAY prior to this.. –  Amro Jun 4 '12 at 22:52
Yep, I'm positive. Here's a sample dl.dropbox.com/u/7348856/img_00003.bmp I send the difference of this image and the one after it to wigner. –  Absi Jun 4 '12 at 22:57
@Absi: actually it is an RGB image even though all channels are equal (ndims(img)==3). You need to call RGB2GRAY... –  Amro Jun 4 '12 at 23:05
Ah that's correct. Now it appears to be working. Thanks a million bro. I've got a question for you though; when using the outside value that is multiplied by the double summation (i.e. 4/(MN)) the image turns pitch black. I've changed that to 4/(MdNd) and it displays a good result. Do you have any modest idea why? –  Absi Jun 4 '12 at 23:20

this might not be what you are asking, but it seems (at first glance) that the order of the summations are independent and that instead of {x,y,l,k} you could go {l,k,x,y}. doing this will allow you to evaluate kernel fewer times by keeping it in the outer most loop.

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This is a splendid suggestion; the function improved to an extraordinary degree. I salute you. –  Absi May 25 '12 at 19:58
+1 for Laurbert515. @Absi, if you decide that this answer is helpful (even if you don't see it as the complete answer to your question), you should at least upvote it by pressing the up arrow (▲). –  Eitan T May 25 '12 at 21:12
@EitanT I did try to upvote; unfortunately I need to have a reputation of 15. My apologies to Laurbert515. –  Absi May 25 '12 at 21:15
@Absi Oh okay, I didn't pay attention to your the amount of you reputation. My apologies to you, sir :) –  Eitan T May 25 '12 at 21:18
@EitanT It's ok man, thank you for taking the time to help me :) –  Absi May 25 '12 at 21:29

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