The squared modulus of the Fourier transform of a series is defined as the *energy spectral density* (ESD). You need to divide the ESD by the length of the series to convert to an estimate of *power spectral density* (PSD).

## Units

The units of a PSD are [units]**2/[frequency] where [units] represents the units of your original series.

## Normalization

To check for proper normalization, one can numerically integrate the PSD of a white noise (with known variance). If the integrated spectrum equals the variance of the series, the normalization is correct. A factor of 2 (too low) is not incorrect, though, and may indicate the PSD is normalized to be *double-sided*; in that case, just multiply by 2 and you have a properly normalized, single-sided PSD.

Using numpy, the randn function generates pseudo-random numbers that are Gaussian distributed. For example

```
10 * np.random.randn(1, 100)
```

produces a 1-by-100 array with mean=0 and variance=100. If the sampling frequency is, say, 1-Hz, the *single-sided* PSD will theoretically be flat at 200 units**2/Hz, from [0,0.5] Hz; the integrated spectrum would thus be 10, equaling the variance of the series.

*Update*

I modified the example included in the python code you linked to demonstrate the normalization for a normally distributed series of length 20, with variance 1, and sampling frequency 10:

```
import numpy
import lomb
numpy.random.seed(999)
nd = 20
fs = 10
x = numpy.arange(nd)
y = numpy.random.randn(nd)
fx, fy, nout, jmax, prob = lomb.fasper(x, y, 1., fs)
fNy = fx[-1]
fy = fy/fs
Si = numpy.mean(fy)*fNy
print fNy, Si, Si*2
```

This gives, for me:

```
5.26315789474 0.482185882163 0.964371764327
```

which shows you a few things:

- The "Nyquist" frequency asked for is actually the sampling frequency.
- The result needs to be divided by the sampling frequency.
- The output is normalized for a double-sided PSD, so multiplying by 2 makes the integrated spectrum nearly 1.