Mercurial > hg > smallbox
view util/SMALL_swipe.m @ 40:6416fc12f2b8
(none)
author | idamnjanovic |
---|---|
date | Mon, 14 Mar 2011 15:35:24 +0000 |
parents | fc395272d53e |
children | 8e660fd14774 |
line wrap: on
line source
function [p,s] = SMALL_swipe(X,fs, f, plim,dlog2p,dERBs,woverlap,sTHR) % % % Centre for Digital Music, Queen Mary, University of London. % This file copyright 2009 Ivan Damnjanovic. % % This program is free software; you can redistribute it and/or % modify it under the terms of the GNU General Public License as % published by the Free Software Foundation; either version 2 of the % License, or (at your option) any later version. See the file % COPYING included with this distribution for more information. % % % This is modified swipep MATLAB code that is working directly in spectral % domain and uses only one window size. The results are suboptimal % comparing to original code. It is also converted to SWIPE which uses all % the harmonics of the signal. % % SWIPEP Pitch estimation using SWIPE'. % P = SWIPEP(X,Fs,[PMIN PMAX],DT,DLOG2P,DERBS,STHR) estimates the pitch % of the vector signal X every DT seconds. The sampling frequency of % the signal is Fs (in Hertz). The spectrum is computed using a Hann % window with an overlap WOVERLAP between 0 and 1. The spectrum is % sampled uniformly in the ERB scale with a step size of DERBS ERBs. The % pitch is searched within the range [PMIN PMAX] (in Hertz) with samples % distributed every DLOG2P units on a base-2 logarithmic scale of Hertz. % The pitch is fine-tuned using parabolic interpolation with a resolution % of 1 cent. Pitch estimates with a strength lower than STHR are treated % as undefined. % % [P,T,S] = SWIPEP(X,Fs,[PMIN PMAX],DT,DLOG2P,DERBS,WOVERLAP,STHR) % returns the times T at which the pitch was estimated and the pitch % strength S of every pitch estimate. % % P = SWIPEP(X,Fs) estimates the pitch using the default settings PMIN = % 30 Hz, PMAX = 5000 Hz, DT = 0.001 s, DLOG2P = 1/48 (48 steps per % octave), DERBS = 0.1 ERBs, WOVERLAP = 0.5, and STHR = -Inf. % % P = SWIPEP(X,Fs,...,[],...) uses the default setting for the parameter % replaced with the placeholder []. % % REMARKS: (1) For better results, make DLOG2P and DERBS as small as % possible and WOVERLAP as large as possible. However, take into account % that the computational complexity of the algorithm is inversely % proportional to DLOG2P, DERBS and 1-WOVERLAP, and that the default % values have been found empirically to produce good results. Consider % also that the computational complexity is directly proportional to the % number of octaves in the pitch search range, and therefore , it is % recommendable to restrict the search range to the expected range of % pitch, if any. (2) This code implements SWIPE', which uses only the % first and prime harmonics of the signal. To convert it into SWIPE, % which uses all the harmonics of the signal, replace the word % PRIMES with a colon (it is located almost at the end of the code). % However, this may not be recommendable since SWIPE' is reported to % produce on average better results than SWIPE (Camacho and Harris, % 2008). % % EXAMPLE: Estimate the pitch of the signal X every 10 ms within the % range 75-500 Hz using the default resolution (i.e., 48 steps per % octave), sampling the spectrum every 1/20th of ERB, using a window % overlap factor of 50%, and discarding samples with pitch strength % lower than 0.2. Plot the pitch trace. % [x,Fs] = wavread(filename); % [p,t,s] = swipep(x,Fs,[75 500],0.01,[],1/20,0.5,0.2); % plot(1000*t,p) % xlabel('Time (ms)') % ylabel('Pitch (Hz)') % % REFERENCES: Camacho, A., Harris, J.G, (2008) "A sawtooth waveform % inspired pitch estimator for speech and music," J. Acoust. Soc. Am. % 124, 1638-1652. if ~ exist( 'plim', 'var' ) || isempty(plim), plim = [30 5000]; end %if ~ exist( 'dt', 'var' ) || isempty(dt), dt = 0.001; end if ~ exist( 'dlog2p', 'var' ) || isempty(dlog2p), dlog2p = 1/48; end if ~ exist( 'dERBs', 'var' ) || isempty(dERBs), dERBs = 0.05; end % if ~ exist( 'woverlap', 'var' ) || isempty(woverlap) % woverlap = 0.5; % elseif woverlap>1 || woverlap<0 % error('Window overlap must be between 0 and 1.') % end if ~ exist( 'sTHR', 'var' ) || isempty(sTHR), sTHR = -Inf; end %t = [ 0: dt: length(x)/fs ]'; % Times % Define pitch candidates log2pc = [ log2(plim(1)): dlog2p: log2(plim(2)) ]'; pc = 2 .^ log2pc; S = zeros( length(pc), 1 ); % Pitch strength matrix % Determine P2-WSs %logWs = round( log2( 8*fs ./ plim ) ); ws = [2822];%2.^[ logWs(1): -1: logWs(2) ]; % P2-WSs pO = 8 * fs ./ ws; % Optimal pitches for P2-WSs % Determine window sizes used by each pitch candidate d = 1 + log2pc - log2( 8*fs./ws(1) ); % Create ERB-scale uniformly-spaced frequencies (in Hertz) fERBs = erbs2hz([ hz2erbs(min(pc)/4): dERBs: hz2erbs(fs/2) ]'); for i = 1 : length(ws) %dn = max( 1, round( 8*(1-woverlap) * fs / pO(i) ) ); % Hop size % Zero pad signal %xzp = [ zeros( ws(i)/2, 1 ); x(:); zeros( dn + ws(i)/2, 1 ) ]; % Compute spectrum %w = hanning( ws(i) ); % Hann window %o = max( 0, round( ws(i) - dn ) ); % Window overlap %[ X, f, ti ] = specgram( xzp, ws(i), fs, w, o ); % Select candidates that use this window size if length(ws) == 1 j=[1:size(pc)]'; k = []; elseif i == length(ws) j=find(d-i>-1); k=find(d(j)-i<0); elseif i==1 j=find(d-i<1); k=find(d(j)-i>0); else j=find(abs(d-i)<1); k=1:length(j); end % Compute loudness at ERBs uniformly-spaced frequencies fERBs = fERBs( find( fERBs > pc(1)/4, 1, 'first' ) : end ); L = sqrt( max( 0, interp1( f, X, fERBs, 'spline', 0) ) ); % Compute pitch strength Si = pitchStrengthAllCandidates( fERBs, L, pc ); % Interpolate pitch strength at desired times % if size(Si,2) > 1 % warning off MATLAB:interp1:NaNinY % Si = interp1( ti, Si', t, 'linear', NaN )'; % warning on MATLAB:interp1:NaNinY % else % Si = repmat( NaN, length(Si),1 ); % end % Add pitch strength to combination % lambda = d( j(k) ) - i; mu = ones( size(j) ); % mu(k) = 1 - abs( lambda ); S(j,:) = S(j,:) + repmat(mu,1,size(Si,2)) .* Si; end % Fine tune pitch using parabolic interpolation p = repmat( NaN, size(S,2), 1 ); s = repmat( NaN, size(S,2), 1 ); for j = 1 : size(S,2) [ s(j), i ] = max( S(:,j), [], 1 ); if s(j) < sTHR, continue, end if i == 1 || i == length(pc) p(j) = pc(i); else I = i-1 : i+1; tc = 1 ./ pc(I); ntc = ( tc/tc(2) - 1 ) * 2*pi; c = polyfit( ntc, S(I,j), 2 ); ftc = 1 ./ 2.^[ log2(pc(I(1))): 1/12/100: log2(pc(I(3))) ]; nftc = ( ftc/tc(2) - 1 ) * 2*pi; [s(j) k] = max( polyval( c, nftc ) ); p(j) = 2 ^ ( log2(pc(I(1))) + (k-1)/12/100 ); % if (p(j)-pc(I(1)))<0.75*abs(p(j)-pc(I(2))) % p(j)=pc(I(1)); % elseif (pc(I(3))-p(j))<0.75*abs(p(j)-pc(I(2))) % p(j)=pc(I(3)); % else p(j)=pc(I(2)); % end end end function S = pitchStrengthAllCandidates( f, L, pc ) % Create pitch strength matrix S = zeros( length(pc), size(L,2) ); % Define integration regions k = ones( 1, length(pc)+1 ); for j = 1 : length(k)-1 k(j+1) = k(j) - 1 + find( f(k(j):end) > pc(j)/4, 1, 'first' ); end k = k(2:end); % Create loudness normalization matrix N = sqrt( flipud( cumsum( flipud(L.*L) ) ) ); for j = 1 : length(pc) % Normalize loudness warning off MATLAB:divideByZero NL = L(k(j):end,:) ./ repmat( N(k(j),:), size(L,1)-k(j)+1, 1); warning on MATLAB:divideByZero % Compute pitch strength S(j,:) = pitchStrengthOneCandidate( f(k(j):end), NL, pc(j) ); end function S = pitchStrengthOneCandidate( f, NL, pc ) n = fix( f(end)/pc - 0.75 ); % Number of harmonics if n==0, S=NaN; return, end k = zeros( size(f) ); % Kernel % Normalize frequency w.r.t. candidate q = f / pc; % Create kernel for i = [ 1:n] % primes(n) ] a = abs( q - i ); % Peak's weigth p = a < .25; k(p) = cos( 2*pi * q(p) ); % Valleys' weights v = .25 < a & a < .75; k(v) = k(v) + cos( 2*pi * q(v) ) / 2; end % Apply envelope k = k .* sqrt( 1./f ); % K+-normalize kernel k = k / norm( k(k>0) ); % Compute pitch strength S = k' * NL; function erbs = hz2erbs(hz) erbs = 21.4 * log10( 1 + hz/229 ); function hz = erbs2hz(erbs) hz = ( 10 .^ (erbs./21.4) - 1 ) * 229;