# Matlab: Finding dominant frequencies in a frame of audio data

I am pretty new to Matlab and I am trying to write a simple frequency based speech detection algorithm. The end goal is to run the script on a wav file, and have it output start/end times for each speech segment. If use the code:

``````fr = 128;
[ audio, fs, nbits ] = wavread(audioPath);
spectrogram(audio,fr,120,fr,fs,'yaxis')
``````

I get a useful frequency intensity vs. time graph like this:

By looking at it, it is very easy to see when speech occurs. I could write an algorithm to automate the detection process by looking at each x-axis frame, figuring out which frequencies are dominant (have the highest intensity), testing the dominant frequencies to see if enough of them are above a certain intensity threshold (the difference between yellow and red on the graph), and then labeling that frame as either speech or non-speech. Once the frames are labeled, it would be simple to get start/end times for each speech segment.

My problem is that I don't know how to access that data. I can use the code:

``````[S,F,T,P] = spectrogram(audio,fr,120,fr,fs);
``````

to get all the features of the spectrogram, but the results of that code don't make any sense to me. The bounds of the S,F,T,P arrays and matrices don't correlate to anything I see on the graph. I've looked through the help files and the API, but I get confused when they start throwing around algorithm names and acronyms - my DSP background is pretty limited.

How could I get an array of the frequency intensity values for each frame of this spectrogram analysis? I can figure the rest out from there, I just need to know how to get the appropriate data.

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``````  %% Time specifications:
Fs = 100;                      % samples per second
dt = 1/Fs;                     % seconds per sample
StopTime = 1;                  % seconds
t = (0:dt:StopTime-dt)';
N = size(t,1);
%% Sine wave:
Fc = 12;                       % hertz
x = cos(2*pi*Fc*t);
%% Fourier Transform:
X = fftshift(fft(x));
%% Frequency specifications:
dF = Fs/N;                      % hertz
f = -Fs/2:dF:Fs/2-dF;           % hertz
%% Plot the spectrum:
figure;
plot(f,abs(X)/N);
xlabel('Frequency (in hertz)');
title('Magnitude Response');
``````

Why do you want to use complex stuff?

a nice and full solution may found in http://dsp.stackexchange.com/questions/1522/simplest-way-of-detecting-where-audio-envelopes-start-and-stop

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I'm confused - where does the actual audio data come into that equation? –  Cbas Nov 27 '12 at 23:13
I mean, I get that I can get whatever data that equation is giving me by doing 'q = 10*log(abs(fftshift(fft(audio))));', but again, I'm not sure what data that is. It's a 335570x1 vector with a min of 0.0218 and a max of 497 - what is it supposed to be representing? –  Cbas Nov 27 '12 at 23:32
you should split the buffer to smaller packets and analyze each –  0x90 Nov 28 '12 at 3:42

Have a look at the STFT (short-time fourier transform) or (even better) the DWT (discrete wavelet transform) which both will estimate the frequency content in blocks (windows) of data, which is what you need if you want to detect sudden changes in amplitude of certain ("speech") frequencies.

Don't use a FFT since it calculates the relative frequency content over the entire duration of the signal, making it impossible to determine when a certain frequency occured in the signal.

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