You're right, "the" Fast Fourier transform is just a name for *any* algorithm that computes the discrete Fourier transform in O(n log n) time, and there are several such algorithms.

Here's the simplest explanation of the DFT and FFT as I think of them, and also examples for small N, which may help. (Note that there are alternative interpretations, and other algorithms.)

## Discrete Fourier transform

Given `N`

numbers f_{0}, f_{1}, f_{2}, …, f_{N-1}, the DFT gives a different set of `N`

numbers.

Specifically: Let ω be a primitive *N*th root of 1 (either in the complex numbers or in some finite field), which means that ω^{N}=1 but no smaller power is 1. You can think of the f_{k}'s as the coefficients of a polynomial P(x) = ∑f_{k}x^{k}. The *N* new numbers F_{0}, F_{1}, …, F_{N-1} that the DFT gives are the results of **evaluating the polynomial** at powers of ω. That is, for each *n* from 0 to N-1, the new number F_{n} is P(ω^{n}) = ∑_{0≤k≤N-1} f_{k}ω^{nk}.

[The reason for choosing ω is that the inverse DFT has a nice form, very similar to the DFT itself.]

Note that finding these F's naively takes O(N^{2}) operations. But we can exploit the special structure that comes from the ω's we chose, and that allows us to do it in O(N log N). Any such algorithm is called the fast Fourier transform.

## Fast Fourier Transform

So here's one way of doing the FFT. I'll replace N with 2N to simplify notation. We have f_{0}, f_{1}, f_{2}, …, f_{2N-1}, and we want to compute P(ω^{0}), P(ω^{1}), … P(ω^{2N-1}) where we can write

P(x) = Q(x) + ω^{N}R(x) with

Q(x) = f_{0} + f_{1}x + … + f_{N-1}x^{N-1}

R(x) = f_{N} + f_{N+1}x + … + f_{2N-1}x^{2N-1}

Now here's the beauty of the thing. Observe that the value at ω^{k+N} is very simply related to the value at ω^{k}:

P(ω^{k+N}) = ω^{N}(Q(ω^{k}) + ω^{N}R(ω^{k})) = R(ω^{k}) + ω^{N}Q(ω^{k}). So the evaluations of Q and R at ω^{0} to ω^{N-1} are enough.

This means that your original problem — of evaluating the 2N-term polynomial P at 2N points ω^{0} to ω^{2N-1} — has been reduced to the two problems of evaluating the N-term polynomials Q and R at the N points ω^{0} to ω^{N-1}. So the running time T(2N) = 2T(N) + O(N) and all that, which gives T(N) = O(N log N).

## Examples of DFT

Note that other definitions put factors of 1/N or 1/√N.

For N=2, ω=-1, and the Fourier transform of (a,b) is (a+b, a-b).

For N=3, ω is the complex cube root of 1, and the Fourier transform of (a,b,c) is (a+b+c, a+bω+cω^{2}, a+bω^{2}+cω). (Since ω^{4}=ω.)

For N=4 and ω=i, and the Fourier transform of (a,b,c,d) is (a+b+c+d, a+bi-c-di, a-b+c-d, a-bi-c+di). In particular, the example in your question: the DFT on (1,0,0,0) gives (1,1,1,1), not very illuminating perhaps.