One can easily draw (pseudo-)random samples from a normal (Gaussian) distribution by using, say, NumPy:

```
import numpy as np
mu, sigma = 0, 0.1 # mean and standard deviation
s = np.random.normal(mu, sigma, 1000)
```

Now, consider the Fast Fourier transform of `s`

:

```
from scipy.fftpack import fft
sHat = fft(s)
```

Considering, presumably, generating Gaussian random numbers **directly in the frequency domain** might be more clever(?) (thus, efficient?) for various applications, and "the Fourier transform of white noise is white noise", and reportedly `sHat`

can be generated directly without the Fourier-transform of `s`

as theoretically shown herein;

Could you please advice novices (like myself) on how to implement such a useful idea? Favourably, a reference to an available implementation that I could not find in the web?

The following is my attempt to code the above theoretical explanation:

```
import numpy as np
from scipy.fftpack import ifft
N = 100
gaussComplex = np.full(shape=N, dtype=complex, fill_value=0.+0.j)
mu, sigma = 0, 1
s = np.random.normal(mu, sigma, N)
iters = np.arange(N) # 0..N-1
# 0..N/2-1
for i, item in enumerate(iters[:N/2]):
gaussComplex[i] = complex(s[i], s[i+N/2])
conjugateGaussComplex = np.conjugate(gaussComplex)
# N/2..N-1
for i, item in enumerate(iters[N/2:]):
gaussComplex[item] = conjugateGaussComplex[N-item]
sNew = ifft(gaussComplex)
```

A comparison of `s`

and `sNew`

reveals the following as I expect that they would be the same:

```
plt.plot(sHat.real, 'blue')
plt.plot(s, 'red')
```