# Plotting power spectrum in python

I have an array with 301 values, which were gathered from a movie clip with 301 frames. This means 1 value from 1 frame. The movie clip is running at 30 fps, so is in fact 10 sec long

Now I would like to get the power spectrum of this "signal" ( with the right Axis). I tried:

`````` X = fft(S_[:,2]);
pl.plot(abs(X))
pl.show()
``````

I also tried:

`````` X = fft(S_[:,2]);
pl.plot(abs(X)**2)
pl.show()
``````

Though I don't think this is the real spectrum.

the signal:

The spectrum:

The power spectrum :

Can anyone provide some help with this ? I would like to have a plot in Hz.

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Why you "don't think this is the real spectrum" ? – Jakub M. Mar 13 '13 at 10:35

Numpy has a convenience function, `np.fft.fftfreq` to compute the frequencies associated with FFT components:

``````from __future__ import division
import numpy as np
import matplotlib.pyplot as plt

data = np.random.rand(301) - 0.5
ps = np.abs(np.fft.fft(data))**2

time_step = 1 / 30
freqs = np.fft.fftfreq(data.size, time_step)
idx = np.argsort(freqs)

plt.plot(freqs[idx], ps[idx])
``````

Note that the largest frequency you see in your case is not 30 Hz, but

``````In [7]: max(freqs)
Out[7]: 14.950166112956811
``````

You never see the sampling frequency in a power spectrum. If you had had an even number of samples, then you would have reached the Nyquist frequency, 15 Hz in your case (although numpy would have calculated it as -15).

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In your comment above, should the frequencies have Hz units rather than the kHz units you have used? – Cabbage soup Mar 17 '15 at 13:27
Indeed, @Sam, thanks for the review, have edited the answer. – Jaime Mar 17 '15 at 13:29

if rate is the sampling rate(Hz), then `np.linspace(0, rate/2, n)` is the frequency array of every point in fft. You can use `rfft` to calculate the fft in your data is real values:

``````import numpy as np
import pylab as pl
rate = 30.0
t = np.arange(0, 10, 1/rate)
x = np.sin(2*np.pi*4*t) + np.sin(2*np.pi*7*t) + np.random.randn(len(t))*0.2
p = 20*np.log10(np.abs(np.fft.rfft(x)))
f = np.linspace(0, rate/2, len(p))
plot(f, p)
``````

signal x contains 4Hz & 7Hz sin wave, so there are two peaks at 4Hz & 7Hz.

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A small correction, when using `fft.rfft`: `p[0] -= 6.02; p[-1] -= 6.02` (`absfft2[0] /= 2; absfft2[-1] /= 2`) -- see e.g. Numerical Recipes p. 653 – denis Dec 7 '13 at 17:20
I think the last line should be `pl.plot(f, p)` in order to run the code . And thank you for your answer it is very didactic. – wancharle Oct 3 '15 at 17:50

From the numpy fft page http://docs.scipy.org/doc/numpy/reference/routines.fft.html:

When the input a is a time-domain signal and A = fft(a), np.abs(A) is its amplitude spectrum and np.abs(A)**2 is its power spectrum. The phase spectrum is obtained by np.angle(A).

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I added the plot with np.abs(A)**2. Though, how can I plot it so that I can seen the Hz ? I doubt it goes from 0 to 301 Hz, when I have exactly 301 samples :P – Ojtwist Mar 13 '13 at 10:13
you have to do yourself: FFT does know only about equally spaced data (like on a regular grid), not physical quantities. – Francesco Montesano Mar 13 '13 at 10:19
Wouldn't it be worth taking a log10 of the result values to get a result in dB? – Laurent Oct 13 '13 at 9:38

Since FFT is symmetric over it's centre, half the values are just enough.

``````import numpy as np
import matplotlib.pyplot as plt

fs = 30.0
t = np.arange(0,10,1/fs)
x = np.cos(2*np.pi*10*t)

xF = np.fft.fft(x)
N = len(xF)
xF = xF[0:N/2]
fr = np.linspace(0,fs/2,N/2)

plt.ion()
plt.plot(fr,abs(xF)**2)
``````
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