# Matching two series of Mfcc coefficients

I have extracted two series MFCC coefficients from two around 30 second audio files consisting of the same speech content. The audio files are recorded at the same location from different sources. An estimation should be made whether the audio contains the same conversation or a different conversation. Currently I have tested a correlation calculation of the two Mfcc series but the result is not very reasonable. Are there best practices for this scenario?

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Why would you use MFCCs to do so? I would try correllating a couple low DFT frequencies over time. –  Efrain Aug 12 '11 at 14:27
What do you mean by "different sources"? Does "same speech content" mean same speaker and same words in the recorded sessions? What problem are you trying to solve? In general I would mean that MFCCs are well suited for this task, but I need you to clarify my questions in order to help you out. Regards –  KlausCPH Aug 26 '11 at 16:48
By "different sources" I mean different microphones at different locations (i.e. different areas in one room) recording the same speaker and same words in the recorded sessions. –  Sney Apr 11 '13 at 22:48

Since the two vectors are effectively histograms, you might want to try calculating the chi-squared distance between the vectors (a common distance measure for histograms).

``````d(i) = sum (x(i) - y(i))^2/(2 * (x(i)+y(i)));
``````

A good (mex) implementation can be found in this toolbox:

http://www.mathworks.com/matlabcentral/fileexchange/15935-computing-pairwise-distances-and-metrics

Call as follows:

``````d = slmetric_pw(X, Y, 'chisq');
``````
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I had the same problem and the solution for it was to match the two arrays of MFCCs using the Dynamic Time Warping algorithm.

After computing the MFCCs you should now have, for each of your two signals, an array where each element contains the MFCCs for a frame (an array of arrays). The first step would be to compute "distances" between every one element of one array and every one element of the other, i.e. distances between every two sets of MFCCs (you could try using the Euclidian Distance for this).

This should leave you with a 2-dimensional array (let's call it "dist") where element (i,j) represents the distance between the MFCCs of the i-th frame in the first signal and the MFCCs of the j-th frame of your second signal.

On this array you can now apply the DTW algorithm:

• dtw(1,1) = dist(1,1)
• dtw(i,j) = min (dtw(i-1, j-1), dtw(i-1, j), dtw(i, j-1)) + dist(i,j).

The value representing the "difference" between your two files is dtw(n,m), where n = nr. of frames in the first signal, m = nr. of frames of the second one.

For further reading, this paper might give you an overall view of applying DTW to MFCCs and this presentation of the DTW algorithm might also help.

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I faced the same problem recently. The best way I found is to use the audio library MIRtoolbox, which is very powerful in terms of audio processing.

After adding this library, the distance of two MFCCs can be easily computed by calling (lower distance <=> similar matches):

``````dist = mirgetdata(mirdist(mfcc1, mfcc2));
``````
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