power spectrum by numpy.fft.fft

The figure I plot via the code below is just a peak around ZERO, no matter how I change the data. My data is just one column which records every timing points of some kind of signal. Is the `time_step` a value I should define according to the interval of two neighbouring points in my data?

``````data=np.loadtxt("timesequence",delimiter=",",usecols=(0,),unpack=True)

ps = np.abs(np.fft.fft(data))**2
time_step = 1

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

pl.plot(freqs[idx], ps[idx])
pl.show()
``````
• Yes, `time_step` should be the timing difference between `data[i+1]` and `data[i]`. That is, if you have two arrays, `t` and `data`, then `time_step = t[1] - t[0]`. It just ends up being a multiplier for `freqs`, so if your output has unexpected form, this probably isn't the problem, as it would just scale it. Nov 19, 2013 at 15:14
• if the data is like [1,2,3,4,5...1000],I mean in the perfect scenario,I receive a signal every second,there should be a peak around 1,right? Nov 19, 2013 at 15:17
• That means that your f(t) = t, and the fourier transform of that is the first derivative of the dirac delta. If you receive a signal at each timestep, then `data = [1, 1, 1, 1]` is what your signal should be for an `fft` Nov 19, 2013 at 15:22
• @questionhang No, I think that is your problem. `fft` takes the signal and you can you use `fftfreq` to get transform the timing points to get the frequency axis on your power spectrum plot. I've provided an example for you that does this. Nov 19, 2013 at 15:23
• If your signal is not approximately symmetric around 0, then it's normal to have a high DC component (index 0 of the fft). Try pre-conditioning your signal by subtracting the average value of all the samples, so that you have approximately as much positive "energy" as negative... Nov 19, 2013 at 15:45

As others have hinted at your signals must have a large nonzero component. A peak at 0 (DC) indicates the average value of your signal. This is derived from the Fourier transform itself. This cosine function cos(0)*ps(0) indicates a measure of the average value of the signal. Other Fourier transform components are cosine waves of varying amplitude which show frequency content at those values.

Note that stationary signals will not have a large DC component as they are already zero mean signals. If you do not want a large DC component then you should compute the mean of your signal and subtract values from that. Regardless of whether your data is 0,...,999 or 1,...,1000, or even 1000, ..., 2000 you will get a peak at 0Hz. The only difference will be the magnitude of the peak since it measures the average value.

``````data1 = arange(1000)
data2 = arange(1000)+1000
dataTransformed3 = data - mean(data)
data4 = numpy.zeros(1000)
data4[::10] = 1 #simulate a photon counter where a 1 indicates a photon came in at time indexed by array.
# we could assume that the sample rate was 10 Hz for example
ps1 = np.abs(np.fft.fft(data))**2
ps2 = np.abs(np.fft.fft(data))**2
ps3 = np.abs(np.fft.fft(dataTransformed))**2

figure()
plot(ps1) #shows the peak at 0 Hz
figure()
plot(ps2) #shows the peak at 0 Hz
figure()
plot(ps3) #shows the peak at 1 Hz this is because we removed the mean value but since
#the function is a step function the next largest component is the 1 Hz cosine wave.
#notice the order of magnitude difference in the two plots.
``````
• My data is arrival time for a series of photons. If single photon arrives uniformly,say,one count per second, a period does exist and it is one second? If photons do not arrive uniformly, I should define a signal intensity by myself? Nov 19, 2013 at 17:55
• Fascinating use case. I think in either case you are ok. In the end your data array should probably not be arange(1000), but should be something like: data = zeros(1000); data[::10] =1 This will indicate that once per second (assuming a sample rate of 10Hz - every 10th value a photon comes in) a photon comes in. The deviation from this you can then measure either directly or wrt the "ideal" photon rate.
– Paul
Nov 19, 2013 at 19:49
• I'm not even sure it's a meaningful use case. Sounds like OP wants something like `hist(diff(arrival_times))` and is just throwing an FFT at it because "I heard FFTs have to do with frequency or something". Apr 26, 2017 at 17:05

Here is a bare-bones example that shows input and output with a peak as you'd expect it:

``````import numpy as np
from scipy.fftpack import rfft, irfft, fftfreq

time   = np.linspace(0,10,2000)
signal = np.cos(5*np.pi*time)

W = fftfreq(signal.size, d=time[1]-time[0])
f_signal = rfft(signal)

import pylab as plt
plt.subplot(121)
plt.plot(time,signal)
plt.subplot(122)
plt.plot(W,f_signal)
plt.xlim(0,10)
plt.show()
``````

I use `rfft` since, more than likely, your input signal is from a physical data source and as such is real.

• yes,my input signal is from a physical source.A cos singal is easy to plot. For a series of timing points,what should signal = np.cos(5*np.pi*time) change to? Nov 19, 2013 at 15:35
• @questionhang Signal is your input data, if it is not periodic, you won't see a peak in the power spectrum (except maybe at 0). Your timing points should match with my variable `time` and your physical signal, measured from your device should be my variable `signal`. Nov 19, 2013 at 15:38
• I get one count every second.It should be periodic.The intensity is scaled by count/s and the intensity is the same all the time in this perfect scenario. Nov 19, 2013 at 15:47
• Both plt.plot(time,signal) and plt.plot(W,f_signal) depend on the definition of signal. Nov 19, 2013 at 16:06
• if signal is a constant and W = fftfreq(signal.size, d=time[1]-time[0]), then plt.plot(W,f_signal) is determined. That means the timing points do not matter? Nov 19, 2013 at 16:19

If you make your data all positive:

``````ps = np.abs(np.fft.fft(data))**2
time_step = 1
``````

then most probably you will create a large 'DC', or 0 Hz component. So if your actual data has little amplitude, compared to that component, it will disappear from the plot, by the autoscaling feature.