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I'm trying to calculate the inverse Fourier Transform of two real functions with a single IFFT. The best and most straightforward explanation I've found so far is here, where it says:

Use the fact that the FFT is linear and form the sum of the first transform plus i times the second. You have two vectors, x1 and x2, with discrete Fourier Transforms X1 and X2 respectively. Then

x1 = Re[ IDFT[ X1 + i X2 ] ]


x2 = Im[ IDFT[ X1 + i X2 ] ].

The problem is that I don't get where the 'i' parameter comes from. Any hint on this would be much appreciated.

Thanks in advance.


After doing some experiments I finally made it work, but now I'm more confused than before as it didn't work as I expected and had to use some imagination to figure out the correct formulas.

I just made up a new complex array where:

Re[n] = X1Re[n] - X2Im[n]
Im[n] = X2Re[n] + X1Im[n]

After doing an IFFT on it x1 = Re and x2 = Im, so wouldn't it be correct to express it like this?

x1 = Re[ IDFT[ X1 - i X2 ] ]
x2 = Im[ IDFT[ X2 + i X1 ] ].
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Just out of interest, what is the use case for doing an IFFT on real data ? While real-valued time domain signals are of course very common I've never seen purely real frequency domain signals ? –  Paul R Jun 14 '11 at 22:50
The IFFT is made on the output of a single FFT which was fed with two real signals. Sorry I think I didn't make myself clear :) –  Trap Jun 14 '11 at 23:18
@eryksun You're right I transcribed it wrong, thanks –  Trap Jun 15 '11 at 7:25
Here's a related question. –  Peter K. Jun 18 '11 at 13:19

2 Answers 2

up vote 4 down vote accepted

Are you wondering what the 'i' represents? In this case, I believe 'i' is referring to sqrt(-1), the imaginary unit vector.


Re[ IDFT[ X1 + i X2 ] ]

will be the 'real' part of that transform (anything without an 'i') and

Im[ IDFT[ X1 + i X2 ] ]

will be the 'imaginary' part of that transform (anything multiplied by an 'i').

It is possible I've misunderstood your question and this answer is much too simplistic; if it is, no insult was intended to your intelligence, I just misunderstood you.

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The "plus i times the second" part is what keeps me wondering. I'm no math guru nor I pretend to be, I just want to add this functionality to my FFT lib while having a little understanding of what it's really doing :) –  Trap Jun 14 '11 at 22:26
It's because of the linearity of FFT, which means it respects addition and scalar multiplication. (i.e. F(a + bc) = F(a) + cF(b). You can exploit this to write your 2 transforms as 1. So instead of doing F(a) first and F(b) next, you do F(a +bi), and then F(a) = anything without an i, and F(b) = anything with an i. 'i' in this case just works like any constant. It's like.... a really advanced way of rewriting (x - 2x + 2) as (x - 2x + 1) + 1 so you can write (x-1)^2 + 1. They're all the same thing, it's just easier to work with one of them. –  uscere90 Jun 14 '11 at 22:31

If you want to ignore the mathematics of complex variables, multiplying by i is just notation for how you swap and scale a pair of vectors to produce another pair of vectors. And the complex vectors X1 and X2 can each be considered to be just pairs of real-valued vectors (with a "complex" relationship under the transforms of interest). The swap and scale makes the two component vectors more easily separable, after some arithmetic and transforms, into the real valued vector of interest.

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