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Here is the context of the problem: I have a DTMF signal in wav format, I have to identify the number sequence it has encoded. I must do so using fast fourier transform in Matlab, implying that I read the wav file using wavread and to identify each number that is seperated by 40ms silence or more.

Here is my code so far:

[signal, fs] = wavread( 'C:\Temp\file.wav' );  % here, fs = 8000Hz

N = 512;                    
T = 1/fs;                   
L = length( signal )        
samples = fs / 1000 * 40    
windows = floor(L / samples) 
t = (1:L)/fs;

figure(1), plot(t, signal);

Here is what the figure 1 looks like, that is the signal read from the wav: enter image description here

How can I effectively split the signal into pieces so that I can then do an FFT on each of the 10 pieces seperately to decode the corresponding numbers?

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Using an FFT for this task is not really appropriate - typically DTMF detection is performed in the time domain using a filter bank, either using conventional filters or the Goertzel algorithm. – Paul R Jan 24 '13 at 6:37
Appropriate? An fft will do the job just fine, even though it might not be the most efficient solution. – KlausCPH Jan 25 '13 at 8:19
Considering I am doing this for an academic purpose, it is mandatory to use the FFT. – JF Beaulieu Jan 25 '13 at 22:04
@JFBeaulieu Hey do you mind if I have a look at your final code? I do have the exact same problem as yours and I was wondering if you would like to share your final code. – Bababarghi Oct 21 '15 at 3:22

I would recommend the following approach:

  • Find the envelope of the signal in the time domain (see Hilbert transform).
  • Smooth the envelope a bit.
  • Take the diff and find peaks to get the onsets of the tones.
  • Use the onsets to pick frames and find the spectrum using fft.
  • Find the index of the max in each of the spectrums and convert them to a frequency.

The tricky part in this is to get a robust onset detector in point 3. The peaks in the difference you pick, has to be of a certain size in order to qualify as on onset. If your tones are of varying strength this might pose a problem, but from your image of the time signal it doesn't seem like a problem.


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up vote 0 down vote accepted

This worked for me:

windowSize = 256;   
nbWindows = floor(L / windowSize);

for i=1:nbWindows
    coeffs = fft(signal((i-1)*windowSize+1:i*windowSize));    

This way it is possible to shift the window until the end of the input signal

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