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I am doing some work, comparing the interpolated fft of the concentrations of some gases over a period, of which is unevenly sampled, with the lomb-scargle periodogram of the same data. I am using scipy's fft function to calculate the fourier transform and then squaring the modulus of this to give what I believe to be the power spectral density, in units of parts per billion(ppb) squared.

I can get the lomb-scargle plot to match almost the exact pattern as the FFT but never the same scale of magnitude, the FFT power spectral density always is higher, even though I thought the lomb-scargle power was power spectral density. Now the lomb code I am using:http://www.astropython.org/snippet/2010/9/Fast-Lomb-Scargle-algorithm, normalises the dataset taking away the average and dividing by 2 times the variance from the data, therefore I have normalised the FFT data in the same manner, but still the magnitudes do not match.

Therefore I did some more research and found that the normalised lomb-scargle power could unitless and therefore I cannot the plots match. This leads me to the 2 questions:

  1. What units (if any) are the power spectral density of a normalised lim-scargle perioogram in?

  2. How would I proceed to match my fft plot with my lomb-scargle plot, in terms of magnitude and pattern?

Thank you.

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1 Answer 1

up vote 3 down vote accepted

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).


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


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.


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
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:

  1. The "Nyquist" frequency asked for is actually the sampling frequency.
  2. The result needs to be divided by the sampling frequency.
  3. The output is normalized for a double-sided PSD, so multiplying by 2 makes the integrated spectrum nearly 1.
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Hello, thank you very much, this has been of great help to me. However, I have calculated the outputted mean, variance and integration of the lomb periodograms, from the lomb code I have been using. The mean is 1.00384639869, variance is 1743.88416724, and integrated spectrum = 11.9433669652. I am struggling to understand what is going on, or if the data is at all normalised? (even if it says so in the code). –  DeneBowdalo Feb 19 '13 at 14:37
Are you using a white noise series? What is the variance? What is the sampling frequency? Without more information (e.g. code) I can't really help. –  Andy Barbour Feb 20 '13 at 6:15
I added an example; hopefully it will help you find the source of your normalization discrepancy. Good luck. –  Andy Barbour Feb 20 '13 at 6:46
A huge thank you, everything is perfectly normalised and matching up now. Awesome. –  DeneBowdalo Feb 22 '13 at 0:02

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