I want numerically compute the FFT on a numpy array Y. For testing, I'm using the Gaussian function Y = exp(-x^2). The (symbolic) Fourier Transform is Y' = constant * exp(-k^2/4).

```
import numpy
X = numpy.arange(-100,100)
Y = numpy.exp(-(X/5.0)**2)
```

The naive approach fails:

```
from numpy.fft import *
from matplotlib import pyplot
def plotReIm(x,y):
f = pyplot.figure()
ax = f.add_subplot(111)
ax.plot(x, numpy.real(y), 'b', label='R()')
ax.plot(x, numpy.imag(y), 'r:', label='I()')
ax.plot(x, numpy.abs(y), 'k--', label='abs()')
ax.legend()
Y_k = fftshift(fft(Y))
k = fftshift(fftfreq(len(Y)))
plotReIm(k,Y_k)
```

real(Y_k) jumps between positive and negative values, which correspond to a jumping phase, which is not present in the symbolic result. This is certainly not desirable. (The result is technically correct in the sense that abs(Y_k) gives the amplitudes as expected ifft(Y_k) is Y.)

Here, the function fftshift() renders the array k monotonically increasing and changes Y_k accordingly. The pairs zip(k, Y_k) are not changed by applying this operation to both vectors.

This changes appears to fix the issue:

```
Y_k = fftshift(fft(ifftshift(Y)))
k = fftshift(fftfreq(len(Y)))
plotReIm(k,Y_k)
```

**Is this the correct way to employ the fft() function if monotonic Y and Y_k are required?**

The reverse operation of the above is:

```
Yx = fftshift(ifft(ifftshift(Y_k)))
x = fftshift(fftfreq(len(Y_k), k[1] - k[0]))
plotReIm(x,Yx)
```

For this case, the documentation clearly states that Y_k must be sorted compatible with the output of fft() and fftfreq(), which we can achieve by applying ifftshift().

Those questions have been bothering me for a long time: Are the output and input arrays of both fft() and ifft() always such that `a[0] should contain the zero frequency term, a[1:n/2+1] should contain the positive-frequency terms, and a[n/2+1:] should contain the negative-frequency terms, in order of decreasingly negative frequency`

[numpy reference], where 'frequency' is the independent variable?

The answer on Fourier Transform of a Gaussian is not a Gaussian does not answer my question.