# Correct usage of fft2 and fftshift for shape from shading

I am attempting to recreate a classical shape from shading algorithm seen in the Trucco/Verri text "Introductory Techniques for 3d Computer Vision", but I am having a hard time understanding the fft function in matlab. Essentially, I need to use the integrability constraint to get the depth (Z) of an image. I am not sure when to use fftshift or not in this scenario. Here is the code I have so far. Based on http://www.mathworks.com/matlabcentral/newsreader/view_thread/285244 I basically wrapped all my fft2s in fftshifts, but I don't think this is the correct usage. Could someone please explain to me the usage and what I am doing wrong? Thank you. Basically, I'm trying to take my p and q (values which are the updates based on pixel intensities) transform them into the Fourier domain so as to use them in the equation C. Then I want to transform the Equation C back to the time domain because that will give me Z the depth. I also want to update P and Q based on C in the Fourier Domain.

``````    wx = (2.* pi .* x) ./ m;
wy = (2.* pi .* y) ./ n;
wx = ifftshift(wx); wy=ifftshift(wy);

Cp = fftshift(fft2(fftshift(p)));
Cq = fftshift(fft2(fftshift(q)));
C = -1i.*(wx .* Cp + wy .* Cq)./(wx.^2 + wy.^2);
Z = abs((ifft2(ifftshift(C))));
p = ifftshift(ifft2(ifftshift(1i * wx .* C)));
q = ifftshift(ifft2(ifftshift(1i * wy .* C)));
``````
• It would help if you could say a little more about what you are trying to do. As it stands, your code will not run, and is without any context about what the pieces mean. – nispio Oct 25 '13 at 20:41
• Hi I added some explanation of the code, I hope that is clearer now, basically I want to transform p and q to the fourier domain, create another equation C in the fourier domain and then go back to the Time Domain and the equation C should give Z. – user2009114 Oct 26 '13 at 2:01

This is a tricky question because in general there is not a right answer. There may be some wrong answers though. I will try to explain. If the answer get a little bit too wordy, you can always just skip down to the summary section and see if it helps.

# Gotchas

Gotcha #1:

When you use Matlab's `fft` (or in your case `fft2`) function, the first element of the output (in your case `X(1,1)`) represents the DC bias. If you subsequently call `fftshift` on your output, everything gets shifted around in a way that places the DC bias at the center. In the 2-dimensional case, it looks something like this:

Notice that the point that was at the top-left corner of block 1 gets moved to the center. While this is a perfectly valid representation of the data, we have to be careful because we have changed the meaning of the (1,1) bin. If I were to attempt an inverse transform at this point, the output would be wrong!

``````B = ifft2(fft2(A));            % B is equal to A
C = ifft2(fftshift(fft2(A)));  % C is not equal to A
``````

Gotcha #2:

The `ifftshift` function should be thought of as the inverse of the `fftshift` operation. It should not be thought of as a shift that applies to `ifft` operation. For this reason, I feel that the function names are very misleading.

In my experience, it is most common for an `ifftshift` to precede an `fft`/`ifft` function, and for an `fftshift` to follow `fft`/`ifft` function. In fact, I would go so far as to say that if you ever find yourself doing one of the following things, you have probably made a mistake:

``````B = ifftshift(ifft(A));        % Don't do this
C = fft(fftshift(A));          % Don't do this either
``````

The following helpful note is found in the Matlab documentation for `ifftshift`

Note: `ifftshift` will undo the results of `fftshift`. If the matrix `X` contains an odd number of elements, `ifftshift(fftshift(X))` must be done to obtain the original `X`. Simply performing `fftshift(X)` twice will not produce `X`.

For example:

``````B = ifftshift(fftshift(A));    % B is equal to A
C = fftshift(fftshift(A));     % C is not equal to A
``````

Gotcha #3:

The DFT has many interesting properties, one of which is that the DFT of a real, even sequence is real and even. We can often use this fact as a simple sanity check. If we put a real, even sequence into the `fft` function and get back something back that is not real and even, we have a problem.

We must take careful note of what an even function looks like when it comes to the DFT. The sequence `3 2 1 0 1 2 3` appears to be even, right? The left half is a mirror image of the right half. This would be true if the fourth element of the sequence represented `t=0`. However, because of the way the FFT algorithm is set up, the first element always represents the `t=0` element.

We can remedy the problem by performing an `ifftshift` operation before the FFT in order to shift the center to the first element. Note that for a sequence with even length, the element `x[N/2+1]` is assumed to be the center.

``````A1 = [ 3 2 1 0 1 2 3 ];        % A1 real, even sequence about A1(4)
B1 = fft(ifftshift(A1));       % B1 is a real, even sequence
C1 = fft(A1);                  % C1 is _not_ a real, even sequence
abs(B1) == abs(C1)             % B1 and C1 differ only in phase

A2 = [ 0 1 2 3 3 2 1 ];        % A2 real, even sequence about A2(0)
B2= fft(ifftshift(A2));        % B2 is _not_ a real, even sequence
C2= fft(A2);                   % C2 is a real, even sequence
abs(B2) == abs(C2)             % B2 and C2 differ only in phase
``````

As you can see by the last example, it would be incorrect to say "always use `ifftshift` before `fft`." What if the first element of my data is already the `t=0` element? Then applying `ifftshift` would be the wrong thing to do.

# Summary

In general, `ifftshift` should only be used before applying an `fft`/`ifft`. The `fft` and `ifft` functions always assume that the first element of your data represents `t=0` and `f=0` respectively. The main question you should ask yourself when using these functions is "where does `t=0` (or `f=0`) live in my data?" and "Where do I want them to live?"

In general, `fftshift` should only be used after applying an `fft`/`ifft`. The output of these functions is given such that the first element represents `f=0` and `t=0` respectively. If you want to rearrange your data such that the `f=0` and `t=0` elements appear in the center, then `fftshift` is the right answer.

Without having a more thorough understanding of exactly what the data you are working with represents, it would be impossible to say whether any `ifftshift` or `fftshift` functions are necessary. Note that there are many situations in which one might use `fft`/`fft2` and `ifft`/`ifft2` correctly without ever needing to invoke `fftshift` or `ifftshift`.

• If the matrix has even dimensions, it seems like fftshift(fftshift(A)) is equal to the original matrix A. The same goes for ifftshift(ifftshift(A)). – Arturo Aug 5 '16 at 20:28
• Typo in the last example ? B2= fft(ifftshift(A)); --> B2= fft(ifftshift(A2)); – Dov May 11 '17 at 13:55
• @Dov I think so, thanks. Fixed. – nispio May 11 '17 at 18:15