I have a question if that's ok. I was recently looking for algorithm to calculate MFCCs. I found a good tutorial rather than code so I tried to code it by myself. I still feel like I am missing one thing. In the code below I took FFT of a signal, calculated normalized power, filter a signal using triangular shapes and eventually sum energies corresponding to each bank to obtain MFCCs.
function output = mfcc(x,M,fbegin,fs) MF = @(f) 2595.*log10(1 + f./700); invMF = @(m) 700.*(10.^(m/2595)-1); M = M+2; % number of triangular filers mm = linspace(MF(fbegin),MF(fs/2),M); % equal space in mel-frequency ff = invMF(mm); % convert mel-frequencies into frequency X = fft(x); N = length(X); % length of a short time window N2 = max([floor(N+1)/2 floor(N/2)+1]); % P = abs(X(1:N2,:)).^2./N; % NoFr no. of periodograms mfccShapes = triangularFilterShape(ff,N,fs); % output = log(mfccShapes'*P); end function [out,k] = triangularFilterShape(f,N,fs) N2 = max([floor(N+1)/2 floor(N/2)+1]); M = length(f); k = linspace(0,fs/2,N2); out = zeros(N2,M-2); for m=2:M-1 I = k >= f(m-1) & k <= f(m); J = k >= f(m) & k <= f(m+1); out(I,m-1) = (k(I) - f(m-1))./(f(m) - f(m-1)); out(J,m-1) = (f(m+1) - k(J))./(f(m+1) - f(m)); end end
Could someone please confirm that this is all right or direct me if I made mistake> I tested it on a simple pure tone and it gives me, in my opinion, reasonable answers.
Any help greatly appreciated :)
PS. I am working on how to apply vectorized Cosinus Transform. It looks like I would need a matrix of MxM of transform coefficients but I did not find any source that would explain how to do it.