It's not really a programming question, and is not specific to `numpy`

. Briefly, the absolute value of the complex number (`sqrt(x.real**2 + x.imag**2)`

, or `numpy.abs()`

) is the amplitude.

More detailed, when you apply FFT to an array `X`

(which, say, contains a number of samples of a function `X(t)`

at different values of `t`

), you try to represent it as a sum of "plane waves" `exp(i w t)`

(where `i`

is an imaginary unit, and `w`

is a real-valued frequency) with different values of `w`

. That is, you want something like

```
X = A exp(i w1 t) + B exp(i w2 t) + ...
```

An FFT returns you these coefficients `A`

, `B`

etc corresponding to some fixed frequencies `w1`

, `w2`

etc (in `numpy`

, you can get their values from fftfreq()).

Now, these coefficients are, in general, complex. A complex number `A`

can be represented as a combination of "amplitude" and "phase" as:

```
A = r exp(i p)
```

where `r`

(`== numpy.abs(A)`

) is the amplitude, and `p`

(`== numpy.angle(A)`

) is the phase, both real values. If you substitute it into the term in the FFT expansion, you get

```
r exp(i p) exp(i w t) == r exp(i (w t + p))
```

So, the amplitude `r`

changes the absolute value of the term, and the phase `p`

, well, shifts the phase. Therefore, in order to get the array of amplitudes from the result of an FFT, you need to apply `numpy.abs`

to it.

But I would really suggest you to read something on FFT theory, there's plenty of information around, for instance wiki.