Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free, no registration required.

I want to do a time-frequency analysis of an EEG signal. I found the GSL wavelet function for computing wavelet coefficients. How can I extract actual frequency bands (e.g. 8 - 12 Hz) from that coefficients? The GSL manual says:

For the forward transform, the elements of the original array are replaced by the discrete wavelet transform f_i -> w_{j,k} in a packed triangular storage layout, where J is the index of the level j = 0 ... J-1 and K is the index of the coefficient within each level, k = 0 ... (2^j)-1. The total number of levels is J = \log_2(n).

The output data has the following form, (s_{-1,0}, d_{0,0}, d_{1,0}, d_{1,1}, d_{2,0}, ..., d_{j,k}, ..., d_{J-1,2^{J-1}-1})

If I understand that right an output array data[] contains at position 1 (e.g. data[1]) the amplitude of the frequency band 2^0 = 1 Hz, and

data[2] = 2^1 Hz  
data[3] = 2^1 Hz  
data[4] = 2^2 Hz  
until  
data[7] = 2^2 Hz  
data[8] = 2^3 Hz

and so on ...

That means I have only the amplitudes for the frequencies 1 Hz, 2 Hz, 4 Hz, 8 Hz, 16 Hz, ... How can I get e.g. the amplitude of a frequency component oscillating at 5.3 Hz? How can I get the amplitude of a whole frequency range, e.g. the amplitude of 8 - 13 Hz? Any recommendations how to get a good time-frequency distribution?

share|improve this question

1 Answer 1

up vote 8 down vote accepted

I'm not sure how familiar you are with general signal processing, so I'll try to be clear, but not chew the food for you.

Wavelets are essentially filter banks. Each filter splits a given signal into two non-overlapping independent high frequency and low frequency subbands such that it can then be reconstructed by the means of an inverse transform. When such filters are applied continually, you get a tree of filters with output of one fed into the next. The simplest, and the most intuitive way to build such tree is as follows:

  • Decompose a signal into low frequency (approximation) and high frequency (detail) components
  • Take the low frequency component, and perform the same processing on that
  • Keep going until you've processed the required number of levels

The reason for this is that you can then downsample the resulting approximation signal. For example, if your filter splits a signal with sampling frequency (Fs) 48000 Hz -- which yields maximum frequency of 24000 Hz by Nyquist Theorem -- into 0 to 12000 Hz approximation component and 12001 to 24000 Hz detail component, you can then take every second sample of the approximation component without aliasing, essentially decimating the signal. This is widely used in signal and image compression.

According to this description, at level one you split your frequency content down the middle and create two separate signals. Then you take your lower frequency component and split it down the middle again. You now get three components in total: 0 to 6000 Hz, 6001 to 12000 Hz, and 12001 to 24000 Hz. You see that the two newer components are both half the bandwidth of the first detail component. You get this sort of a picture:

enter image description here

This correlates with the bandwidths you describe above (2^1 Hz, 2^2 Hz, 2^3 Hz and so on). However, using a broader definition of a filter bank, we can arrange the above tree structure as we like, and it will still remain a filter bank. For example, we can feed both approximation and detail component to to split into two high-frequency and low-frequency signals like so

enter image description here

If you look at it carefully, you see that both high and low frequency components down the middle in their frequencies and as a result you get a uniform filter bank whose frequency separation looks more like this:

enter image description here

Notice that all bands are of the same size. By building a uniform filter bank with N levels, you end up with responses of 2^(N-1) band-bass filters. You can fine-tune your filter bank to eventually give you the desired band (8-13 Hz).

In general, I would not advise you to do this with wavelets. You can go through some literature on designing good band-pass filters and simply build a filter that would only let through 8-13 Hz of your EEG signals. That's what I've done before and it worked quite well for me.

share|improve this answer
    
Phonon, thank you very much for that exhaustive answer and the linked documents! Very interesting read, although I knew most of that stuff already. Unfortunately my question is left unanswered, it was: how can I tune my wavelet analysis to get those filter banks, I guess it has something to do with sample size or sample count of my input signal. But just as you said, wavelets are probably not the best tool for that, so I'll switch to band-pass filtering. Do you have any recommendations for that (just some cues)? –  Michael Jun 29 '11 at 9:52
    
What is the sampling frequency of your signals? –  Phonon Jun 29 '11 at 12:38

Your Answer

 
discard

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.