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I'm trying to find the fundamental frequencies present in a piano recording using MATLAB. These are the steps I've followed;

  1. Find the envelop of the signal

  2. Find the note onsets

  3. perform FFT between each onset

  4. Harmonic product spectrum.

It's when I try to implement the HPS algorithm that I face a "dimensions don't agree" error. This is the whole code that I've used.

[song,FS] = wavread('C major.wav');

P = 20000;
N=length(song);                     % length of song
t=0:1/FS:(N-1)/FS;                  % define time period

song = sum(song,2);                        

% Plot time domain signal
          title('Wave File')
          xlabel('Length (in seconds)')
          %ylim([-1.1 1.1])
          xlim([0 N/FS])

%----------------------Finding the envelope of the signal-----------------%
% Gaussian Filter
x = linspace( -1, 1, P);                      % create a vector of P values between -1 and 1 inclusive
sigma = 0.335;                                % standard deviation used in Gaussian formula
myFilter = -x .* exp( -(x.^2)/(2*sigma.^2));  % compute first derivative, but leave constants out
myFilter = myFilter / sum( abs( myFilter ) ); % normalize

% Plot Gaussian Filter
         title('Edge Detection Filter')

% fft convolution
myFilter = myFilter(:);                         % create a column vector
song(length(song)+length(myFilter)-1) = 0;      %zero pad song
myFilter(length(song)) = 0;                     %zero pad myFilter
edges =ifft(fft(song).*fft(myFilter));

tedges=edges(P:N+P-1);                      % shift by P/2 so peaks line up w/ edges
tedges=tedges/max(abs(tedges));                 % normalize

%---------------------------Onset Detection-------------------------------%
% Finding peaks
maxtab = [];
mintab = [];
x = (1:length(tedges));
min1 = Inf;
max1 = -Inf;
min_pos = NaN; 
max_pos = NaN;

lookformax = 1;
for i=1:length(tedges)

    peak = tedges(i:i);
  if peak > max1, 
      max1 = peak;
      max_pos = x(i); 
  if peak < min1, 
      min1 = peak;
      min_pos = x(i); 

  if lookformax
    if peak < max1-0.001
      maxtab = [maxtab ; max_pos max1];
      min1 = peak; 
      min_pos = x(i);
      lookformax = 0;
    if peak > min1+0.005
      mintab = [mintab ; min_pos min1];
      max1 = peak; 
      max_pos = x(i);
      lookformax = 1;
% % Plot song filtered with edge detector          
         title('Song Filtered With Edge Detector 1')
         xlabel('Time (s)')
         ylim([-1 1.1])
         xlim([0 N/FS])

         hold on;

         plot(maxtab(:,1)/FS, maxtab(:,2), 'ro')
         plot(mintab(:,1)/FS, mintab(:,2), 'ko')

max_col = maxtab(:,1);
peaks_det = max_col/FS;
No_of_peaks = length(peaks_det);

[song,FS] = wavread('C major.wav');

%---------------------------Performing STFT--------------------------------%
h = 1;
for i = 2:No_of_peaks

    song_seg = song(max_col(i-1):max_col(i)-1);
    L = length(song_seg); 
    NFFT = 2^nextpow2(L); % Next power of 2 from length of y
    seg_fft = fft(song_seg,NFFT);%/L;
    U = size(seg_fft,1)

% In harmonic prodcut spectrum, you downsample the fft data several times and multiply all those with the original fft data to get the maximum peak. 
    seg_fft = seg_fft(1 : size(seg_fft,1)/2 );  
    seg_fft = abs(seg_fft);

%HPS: downsampling
for i = 1:length(seg_fft)
    seg_fft2(i,1) = 1;
    seg_fft3(i,1) = 1;
    seg_fft4(i,1) = 1;
%   seg_fft5(i,1) = 1;

for i = 1:floor((length(seg_fft)-1)/2)
    seg_fft2(i,1) = (seg_fft(2*i,1) + seg_fft((2*i)+1,1))/2;

for i = 1:floor((length(seg_fft)-2)/3)
    seg_fft3(i,1) = (seg_fft(3*i,1) + seg_fft((3*i)+1,1) + seg_fft((3*i)+2,1))/3;    

for i = 1:floor((length(seg_fft)-3)/4)
    seg_fft4(i,1) = (seg_fft(4*i,1) + seg_fft((4*i)+1,1) + seg_fft((4*i)+2,1) + seg_fft((4*i)+3,1))/4;

%HPS, PartII: calculate product
p1 = (seg_fft3)  .* (seg_fft4);
p2 = p1.* (seg_fft2);
p3 = p2.* (seg_fft);

HPS, PartIII: find max
[f_y1,I] = max(p3)

 for c = 1 : length(p3)
     if(p3(c,1) == f_y1)
         index = c;

 % Convert that to a frequency
 f_y(h) = (index / NFFT) * FS;

f_y = abs(f_y)';


Before implementing p3 = p2.* (seg_fft); the sizes of seg_fft, seg_fft2, seg_fft3, seg_fft4 all have the same dimensions of 16384 1. Then when I DO implement p3 = p2.* (seg_fft); the size of seg_fft changes to 8192 1 while the sizes of rest remain at 16384 1 thus causing an error in multiplication as the dimensions aren't the same.

I'm really confused as to why this keeps happening and nothing I try seems to work out. Would really REALLY appreciate some help here... If someone could fix this code it'd be a GREAT help... Thanx in advance.. I'm real desperate here......

share|improve this question
The source code is incomplete so it's hard to tell. But I suspect seg_fft to change in size in a loop while seg_fft2 and so on do not. Try replacing the initialization in the first for loop by seg_fft2 = ones(size(seg_fft,1), size(seg_fft,2)); and accordingly for seg_fft3 and seg_fft4. –  Deve Nov 9 '13 at 11:23
Ok I've included the whole code. I anyway tried it the way you mentioned, but it still doesn't work... –  user2482542 Nov 9 '13 at 14:47
Thank you.. That actually did work. I initially had some extra code due to which it didn't work. thank you once again :) –  user2482542 Nov 9 '13 at 16:02
No prob. Just a small addition: using ones(size(seg_fft)); is more elegant, of course. –  Deve Nov 9 '13 at 17:06
Yes that seems to be more neat. Thank you :) –  user2482542 Nov 11 '13 at 7:22

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