Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free.

I'm looking for how to turn the frequency axis in a fft (taken via scipy.fftpack.fftfreq) into a frequency in Hertz, rather than bins or fractional bins.

I tried to code below to test out the FFT:

t = scipy.linspace(0,120,4000)
acc = lambda t: 10*scipy.sin(2*pi*2.0*t) + 5*scipy.sin(2*pi*8.0*t) + 2*scipy.random.random(len(t))

signal = acc(t)

FFT = abs(scipy.fft(signal))
FFT = scipy.fftpack.fftshift(FFT)
freqs = scipy.fftpack.fftfreq(signal.size)


The sampling rate should be 4000 samples / 120 seconds = 33.34 samples/sec.

The signal has a 2.0 Hz signal, a 8.0 Hz signal, and some random noise.

I take the FFT, grab the frequencies, and plot it. The numbers are pretty nonsensical. If I multiply the frequencies by 33.34 (the sampling frequency), then I get peaks at about 8 Hz and 15 Hz, which seems wrong (also, the frequencies should be a factor of 4 apart, not 2!).

Any thoughts on what I'm doing wrong here?

share|improve this question

4 Answers 4

up vote 40 down vote accepted

I think you don't need to do fftshift(), and you can pass sampling period to fftfreq():

import scipy
import scipy.fftpack
import pylab
from scipy import pi
t = scipy.linspace(0,120,4000)
acc = lambda t: 10*scipy.sin(2*pi*2.0*t) + 5*scipy.sin(2*pi*8.0*t) + 2*scipy.random.random(len(t))

signal = acc(t)

FFT = abs(scipy.fft(signal))
freqs = scipy.fftpack.fftfreq(signal.size, t[1]-t[0])

pylab.plot(t, signal)

from the graph you can see there are two peak at 2Hz and 8Hz.

enter image description here

share|improve this answer
Thank you for such a complete answer. hyry, why did u choose to plot 20*scipy.log10(FFT) instead of FFT? –  Archie1986 Dec 24 '13 at 0:38
HYRY provided you a plot with the Y axis in the dB scale, and 20log10 provides the correct conversion for a magnitude spectrum. –  IntrepidBrit May 15 '14 at 16:06

scipy.fftpack.fftfreq(n, d) gives you the frequencies directly. If you set d=1/33.34, this will tell you the frequency in Hz for each point of the fft.

share|improve this answer

The frequency width of each bin is (sampling_freq / num_bins).

A more fundamental problem is that your sample rate is not sufficient for your signals of interest. Your sample rate is 8.3 Hz; you need at least 16Hz in order to capture an 8Hz input tone.1

1. To all the DSP experts; I'm aware that it's actually BW that's relevant, not max frequency. But I'm assuming the OP doesn't want to do undersampled data acquisition.

share|improve this answer
I'm using 4000 samples for 120 seconds -- isn't that 33.3 Hz? That should be more than enough for it, and the numbers are still off... –  nathan lachenmyer Feb 26 '12 at 19:53
@asymptoticdesign: Ah, ok. Your question initially said 1000. Yes, that should be sufficient. Which bin index is the energy appearing in? –  Oliver Charlesworth Feb 26 '12 at 19:59

Your equation is messed up.

fs = 33.33
df1 = 2*pi * (2.0/fs)
df2 = 2*pi * (5.0/fs)
x = [10*sin(n*df1) + 5*sin(n*df2) + 2*random.random() for n in range(4000)]

This gives you 4000 samples of your function, sampled at 33.33 Hz, representing 120 seconds of data.

Now take your FFT. Bin 0 will hold the DC result. Bin 1 will be 33.33, bin 2 will be 66.66, etc..

Edit: I forget to mention that, since your sampling rate is 33.33 Hz, the maximum frequency that can be represented will be fs/2, or 16.665 Hz.

share|improve this answer
-1: No. The total bandwidth is 33.33Hz, not the width of each bin. –  Oliver Charlesworth Feb 26 '12 at 19:59

Your Answer


By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.