`FFT`

to transform the time domain based feature into frequency domain based feature (which I think maybe more robust), and then do some classification or clustering algorithms.
But I'm not sure using what descriptor as frequency domain based feature, since there are amplitude spectrum, power spectrum and phase spectrum of a signal and I've read some references but still got confused about the significance. And what distance (similarity) function should be used as measurement when performing learning algorithms on frequency domain based feature vector(Euclidean distance? Cosine distance? Gaussian function? Chi-kernel or something else?)

Hope someone give me a clue or some material that I can refer to, thanks~**Edit**

`L-1`

norm and plotted its `log power spectrum`

in python and it did show some prominent peaks, below is my code and the figure
```
import numpy as np
import matplotlib.pyplot as plt
sp = np.fft.fft(signal)
freq = np.fft.fftfreq(signal.shape[-1], d = 1.) # time sloth of histogram is 1 hour
plt.plot(freq, np.log10(np.abs(sp) ** 2))
plt.show()
```

And I have several trivial questions to ask to make sure I totally understand your suggestion:

In your second suggestion, you said

Do you mean the horizontal line represent the threshold and all values below it should be assigned to value zero?*"ignore all these values."*

I'm a little bit confused about the meaning of "location" and "width", does "location" refer to the log value of power spectrum (y-axis) and "width" refer to the frequency (x-axis)? If so, how to combine them together as a feature vector and compare two feature vector of*"you may search for the two, three largest peaks and use their location and probably widths as 'Features' for further classification."**"a similar frequency and a similar widths"*?

**Edit**

I replaced `np.fft.fft`

with `np.fft.rfft`

to calculate the positive part and plot both power spectrum and log power spectrum.

```
f, axarr = plt.subplot(2, sharex = True)
axarr[0].plot(freq, np.abs(sp) ** 2)
axarr[1].plot(freq, np.log10(np.abs(sp) ** 2))
plt.show()
```

figure:
Please correct me if I'm wrong:

I think I should keep the last four peaks in*first*figure with

`power = np.abs(sp) ** 2`

and `power[power < threshold] = 0`

because the log power spectrum reduces the difference among each component. And then use the log spectrum of new power as feature vector to feed classifiers.
I also see some reference suggest applying a window function (e.g. Hamming window) before doing fft to avoid **spectral leakage**. My raw data is sampled every 5 ~ 15 seconds and I've applied a histogram on sampling time, is that method equivalent to apply a window function or I still need apply it on the histogram data?