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I saw several codes written where Fourier spectra are divided with the complex conjugate like this:

af = fftn(double(img1));
bf = fftn(double(img2));
cp = af .* conj(bf) ./ abs(af .* conj(bf));

in this script among others.

Is this related to handling complex division? Reading the documentation about the ./ operator, it is stated that it handles complex numbers. So is this wrong?:

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3 Answers 3

up vote 5 down vote accepted

The expressions af./bf and af.*conj(bf)./abs(bf).^2 are completely equivalent in MATLAB, if that's what you're asking. There is no clear connection, however, between that question and the example you've shown. abs(bf).^2 does not appear in the denominator in your example.

The only reason conj() is being used in the code you've shown is because it is the Fourier dual of time inversion

I.e., f(t)<-->F(k) implies f(-t)<--->conj(F(k)), for real-valued time signals f(t).

This has a specific application to time delay analysis using phase correlation.

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There is no reason you cannot element-wise divide Fourier spectra or any other array of complex numbers. The code example you've shown is in no way reflective of such a restriction. –  Matt J Jan 27 '14 at 16:34
Good explanation and link. +1 Phase correlation has a very natural application to image registration. –  chappjc Jan 28 '14 at 2:05

You could rewrite this expression avoiding the conjugation as


However, the given form of the expression has the advantage that you can desingularize the division by adding a small epsilon to the denominator,

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Couldn't you likewise desingularize with (af.*conj(bf))./(1e-40+abs(af.*bf)) ? –  Matt J Jan 28 '14 at 8:08
Yes, since abs(ab)=abs(a)*abs(b)=abs(aconj(b)). What to chose is a question of readability versus number of operations. Some may prefer to have the same notation in both places. Or separate the operations for higher efficiency as in cp=af.*conj(bf); cp=cp./(1e-40+abs(cp)). –  LutzL Jan 28 '14 at 9:19

Consider the following equivalent (within about 1e-15) code:

cpX = exp(1i*(angle(af)-angle(bf)));

You can compute the normalized cross power spectrum as you have shown with the complex conjugate (cp = af .* conj(bf) ./ abs(af .* conj(bf))) or by explicitly subtracting the phase as above.

Considering that the FFT of a shifted impulse is a complex exponential, the cpX equation should give some insight into how "phase correlation" allows you to find a translation between two images. The location of the peak in the inverse FFT gives the translation.

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