# Why use the complex conjugate for Fourier spectra division?

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?:

``````af./bf
``````
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## 3 Answers

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

``````(af./bf)./abs(af./bf).
``````

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

``````(af.*conj(bf))./(1e-40+abs(af.*conj(bf)))
``````
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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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