Mercurial > hg > camir-aes2014
comparison toolboxes/MIRtoolbox1.3.2/AuditoryToolbox/WhiteVowel.m @ 0:e9a9cd732c1e tip
first hg version after svn
| author | wolffd |
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| date | Tue, 10 Feb 2015 15:05:51 +0000 |
| parents | |
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| -1:000000000000 | 0:e9a9cd732c1e |
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| 1 function [output,aCoeff] = WhiteVowel(data,sr,L,pos) | |
| 2 % function [output,aCoeff] = WhiteVowel(data,sr,L,pos) | |
| 3 % | |
| 4 % Speech is often described as having spectral peaks or formants which | |
| 5 % identify the phonetic signal. An interesting experiment, first proposed by | |
| 6 % XXX, filters a speech signal to remove all the formant information at one | |
| 7 % time during the speech. If there are no formant peaks, how can the speech | |
| 8 % be understood? It turns out that processing, much like RASTA, means that | |
| 9 % relative changes in spectrum are the most important, thus the speech signal | |
| 10 % is understood because the formant transitions carry the information. This | |
| 11 % gives speech an important transparency due | |
| 12 % | |
| 13 % This function takes a speech signal (data) with a given sampling rate (sr). | |
| 14 % It then finds the L-order LPC filter that describes the speech at the given | |
| 15 % position (pos ms). The entire speech signal is then filtered with the | |
| 16 % inverse of the LPC filter, effectively turning the speech spectrum at the | |
| 17 % given time white (flat). | |
| 18 | |
| 19 % Chris Pal, Interval, May 1997 | |
| 20 % (c) 1998 Interval Research Corporation | |
| 21 | |
| 22 fr = 20; fs = 30; preemp = .9378; % LPC defaults | |
| 23 | |
| 24 [row col] = size(data); | |
| 25 if col==1 data=data'; end | |
| 26 | |
| 27 nframe = 0; | |
| 28 msfr = round(sr/1000*fr); | |
| 29 msfs = round(sr/1000*fs); | |
| 30 duration = length(data); | |
| 31 msoverlap = msfs - msfr; | |
| 32 frameNumber = floor(pos/1000*sr/msfr); | |
| 33 | |
| 34 frameStart = round(pos/1000*sr - msfs/2); | |
| 35 frameData = data(frameStart:(frameStart+msfs-1)); | |
| 36 aCoeff = proclpc(frameData, sr, L, fr, fs, preemp); | |
| 37 % Calculate the filter response | |
| 38 % by evaluating the z-transform | |
| 39 spec=lpc_spec(aCoeff); | |
| 40 subplot(2,3,1); | |
| 41 plot(spec); | |
| 42 title('LPC Spectral Slice'); | |
| 43 ylabel('Original') | |
| 44 | |
| 45 % Now do the actual whitening filter | |
| 46 output = filter(aCoeff,1,data)'; | |
| 47 | |
| 48 frameData = output(frameStart:(frameStart+msfs-1)); | |
| 49 bCoeff = proclpc(frameData, sr, L, fr, fs, preemp); | |
| 50 spec=lpc_spec(bCoeff); | |
| 51 subplot(2,3,4); | |
| 52 plot(spec); | |
| 53 ylabel('Whitened'); xlabel('FFT Bin'); | |
| 54 | |
| 55 % 256-DFT | |
| 56 origSpec = 20*log10(abs(specgram(data,512,sr,msfs,msoverlap))); | |
| 57 subplot(2,3,2),imagesc(origSpec); axis xy; colormap(1-gray); | |
| 58 title('Spectrogram'); | |
| 59 | |
| 60 synSpec = 20*log10(abs(specgram(output,512,sr,msfs,msoverlap))); | |
| 61 subplot(2,3,5),imagesc(synSpec); axis xy; colormap(1-gray); | |
| 62 xlabel('Frame #'); | |
| 63 | |
| 64 origloc = origSpec(:,frameNumber); origloc=origloc-max(origloc);origmin=min(origloc); | |
| 65 subplot(2,3,3),plot(origloc),title('Spectrogram'), | |
| 66 axis([1 length(origloc) origmin 0]); | |
| 67 | |
| 68 filloc = synSpec(:,frameNumber); filloc=filloc-max(filloc); | |
| 69 subplot(2,3,6),plot(filloc);ylabel('db'); | |
| 70 axis([1 length(origloc) origmin 0]); | |
| 71 xlabel('FFT Bin'); | |
| 72 | |
| 73 function spec=lpc_spec(aCoeff) | |
| 74 gain=0; | |
| 75 cft=0:(1/255):1; | |
| 76 for index=1:size(aCoeff,1) | |
| 77 gain = gain + aCoeff(index)*exp(-i*2*pi*cft).^index; | |
| 78 end | |
| 79 gain = abs(1./gain); | |
| 80 spec = 20*log10(gain(1:128))'; |