Mercurial > hg > camir-aes2014
view toolboxes/MIRtoolbox1.3.2/MIRToolbox/mirsegment.m @ 0:e9a9cd732c1e tip
first hg version after svn
| author | wolffd |
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| date | Tue, 10 Feb 2015 15:05:51 +0000 |
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function [f,p,m,fe] = mirsegment(x,varargin) % f = mirsegment(a) segments an audio signal. It can also be the name of an % audio file or 'Folder', for the analysis of the audio files in the % current folder. The segmentation of audio signal already decomposed % into frames is not available for the moment. % f = mirsegment(...,'Novelty') segments using a self-similarity matrix % (Foote & Cooper, 2003) (by default) % f = mirsegment(...,feature) bases the segmentation strategy on a % specific feature. % 'Spectrum': from FFT spectrum (by default) % 'MFCC': from MFCCs % 'Keystrength': from the key strength profile % 'AutocorPitch': from the autocorrelation function computed as % for pitch extraction. % The option related to this feature extraction can be specified. % Example: mirsegment(...,'Spectrum','Window','bartlett') % mirsegment(...,'MFCC','Rank',1:10) % mirsegment(...,'Keystrength','Weight',.5) % These feature need to be frame-based, in order to appreciate their % temporal evolution. Therefore, the audio signal x is first % decomposed into frames. This decomposition can be controled % using the 'Frame' keyword. % The options available for the chosen strategies can be specified % directly as options of the segment function. % Example: mirsegment(a,'Novelty','KernelSize',10) % f = mirsegment(...,'HCDF') segments using the Harmonic Change Detection % Function (Harte & Sandler, 2006) % f = mirsegment(...,'RMS') segments at positions of long silences. A % frame decomposed RMS is computed using mirrms (with default % options), and segments are selected from temporal positions % where the RMS rises to a given 'On' threshold, until temporal % positions where the RMS drops back to a given 'Off' threshold. % f = mirsegment(...,'Off',t1) specifies the RMS 'Off' threshold. % Default value: t1 = .01 % f = mirsegment(...,'On',t2) specifies the RMS 'On' threshold. % Default value: t2 = .02 % % f = mirsegment(a,s) segments a using the results of a segmentation % analysis s. s can be the peaks detected on an analysis of the % audio for instance. % % f = mirsegment(a,v) where v is an array of numbers, segments a using % the temporal positions specified in v (in s.) % % Foote, J. & Cooper, M. (2003). Media Segmentation using Self-Similarity % Decomposition,. In Proc. SPIE Storage and Retrieval for Multimedia % Databases, Vol. 5021, pp. 167-75. % Harte, C. A. & Sandler, M. B. (2006). Detecting harmonic change in % musical audio, in Proceedings of Audio and Music Computing for % Multimedia Workshop, Santa Barbara, CA. % [f,p] = mirsegment(...) also displays the analysis produced by the chosen % strategy. % For 'Novelty', p is the novelty curve. % For 'HCDF', p is the Harmonic Change Detection Function. % [f,p,m] = mirsegment(...) also displays the preliminary analysis % undertaken in the chosen strategy. % For 'Novelty', m is the similarity matrix. % For 'HCDF', m is the tonal centroid. % [f,p,m,fe] = mirsegment(...) also displays the temporal evolution of the % feature used for the analysis. % f = mirsegment(...,'Novelty') mfc.key = {'Rank','MFCC'}; mfc.type = 'Integers'; mfc.default = 0; mfc.keydefault = 1:13; option.mfc = mfc; K.key = 'KernelSize'; K.type = 'Integer'; K.default = 128; option.K = K; distance.key = 'Distance'; distance.type = 'String'; distance.default = 'cosine'; option.distance = distance; measure.key = {'Measure','Similarity'}; measure.type = 'String'; measure.default = 'exponential'; option.measure = measure; tot.key = 'Total'; tot.type = 'Integer'; tot.default = Inf; option.tot = tot; cthr.key = 'Contrast'; cthr.type = 'Integer'; cthr.default = .1; option.cthr = cthr; frame.key = 'Frame'; frame.type = 'Integer'; frame.number = 2; frame.default = [0 0]; frame.keydefault = [3 .1]; option.frame = frame; ana.type = 'String'; ana.choice = {'Spectrum','Keystrength','AutocorPitch','Pitch'}; ana.default = 0; option.ana = ana; % f = mirsegment(...,'Spectrum') band.choice = {'Mel','Bark','Freq'}; band.type = 'String'; band.default = 'Freq'; option.band = band; mi.key = 'Min'; mi.type = 'Integer'; mi.default = 0; option.mi = mi; ma.key = 'Max'; ma.type = 'Integer'; ma.default = 0; option.ma = ma; norm.key = 'Normal'; norm.type = 'Boolean'; norm.default = 0; option.norm = norm; win.key = 'Window'; win.type = 'String'; win.default = 'hamming'; option.win = win; % f = mirsegment(...,'Silence') throff.key = 'Off'; throff.type = 'Integer'; throff.default = .01; option.throff = throff; thron.key = 'On'; thron.type = 'Integer'; thron.default = .02; option.thron = thron; strat.choice = {'Novelty','HCDF','RMS'}; % should remain as last field strat.default = 'Novelty'; strat.position = 2; option.strat = strat; specif.option = option; p = {}; m = {}; fe = {}; if isa(x,'mirdesign') if not(get(x,'Eval')) % During bottom-up construction of the general design [unused option] = miroptions(@mirframe,x,specif,varargin); type = get(x,'Type'); f = mirdesign(@mirsegment,x,option,{},struct,type); sg = get(x,'Segment'); if not(isempty(sg)) f = set(f,'Segment',sg); else f = set(f,'Segment',option.strat); end else % During top-down evaluation initiation f = evaleach(x); if iscell(f) f = f{1}; end p = x; end elseif isa(x,'mirdata') [unused option] = miroptions(@mirframe,x,specif,varargin); if ischar(option.strat) dx = get(x,'Data'); if size(dx{1},2) > 1 error('ERROR IN MIRSEGMENT: The segmentation of audio signal already decomposed into frames is not available for the moment.'); end if strcmpi(option.strat,'Novelty') if not(option.frame.length.val) if strcmpi(option.ana,'Keystrength') option.frame.length.val = .5; option.frame.hop.val = .2; elseif strcmpi(option.ana,'AutocorPitch') ... || strcmpi(option.ana,'Pitch') option.frame.length.val = .05; option.frame.hop.val = .01; else option.frame.length.val = .05; option.frame.hop.val = 1; end end fr = mirframenow(x,option); if not(isequal(option.mfc,0)) fe = mirmfcc(fr,'Rank',option.mfc); elseif strcmpi(option.ana,'Spectrum') fe = mirspectrum(fr,'Min',option.mi,'Max',option.ma,... 'Normal',option.norm,option.band,... 'Window',option.win); elseif strcmpi(option.ana,'Keystrength') fe = mirkeystrength(fr); elseif strcmpi(option.ana,'AutocorPitch') ... || strcmpi(option.ana,'Pitch') [unused,fe] = mirpitch(x,'Frame'); else fe = fr; end [n m] = mirnovelty(fe,'Distance',option.distance,... 'Measure',option.measure,... 'KernelSize',option.K); p = mirpeaks(n,'Total',option.tot,... 'Contrast',option.cthr,... 'Chrono','NoBegin','NoEnd'); elseif strcmpi(option.strat,'HCDF') if not(option.frame.length.val) option.frame.length.val = .743; option.frame.hop.val = 1/8; end fr = mirframenow(x,option); %[df m fe] = mirhcdf(fr); df = mirhcdf(fr); p = mirpeaks(df); elseif strcmpi(option.strat,'RMS') if not(option.frame.length.val) option.frame.length.val = .05; option.frame.hop.val = .5; end fr = mirframenow(x,option); %[df m fe] = mirhcdf(fr); df = mirrms(fr); fp = get(df,'FramePos'); p = mircompute(@findsilence,df,fp,option.throff,option.thron); end f = mirsegment(x,p); else dx = get(x,'Data'); dt = get(x,'Time'); if isa(option.strat,'mirscalar') ds = get(option.strat,'PeakPos'); fp = get(option.strat,'FramePos'); elseif isa(option.strat,'mirdata') ds = get(option.strat,'AttackPos'); if isempty(ds) || isempty(ds{1}) ds = get(option.strat,'PeakPos'); end xx = get(option.strat,'Pos'); else ds = option.strat; fp = cell(1,length(dx)); end st = cell(1,length(dx)); sx = cell(1,length(dx)); cl = cell(1,length(dx)); for k = 1:length(dx) dxk = dx{k}{1}; % values in kth audio file dtk = dt{k}{1}; % time positions in kth audio file if isa(option.strat,'mirdata') dsk = ds{k}{1}; % segmentation times in kth audio file else dsk = {ds}; end fsk = []; % the structured array of segmentation times % needs to be flatten for j = 1:length(dsk) if isa(option.strat,'mirdata') dsj = dsk{j}; % segmentation times in jth segment else dsj = ds; end if not(iscell(dsj)) dsj = {dsj}; end for m = 1:length(dsj) % segmentation times in mth bank channel if isa(option.strat,'mirscalar') dsm = fp{k}{m}(1,dsj{m}); elseif isa(option.strat,'mirdata') dsm = xx{k}{m}(dsj{m}); else dsm = dsj{m}; end if iscell(dsm) dsm = dsm{1}; end dsm(:,find(dsm(1,:) < dtk(1))) = []; dsm(:,find(dsm(end,:) > dtk(end))) = []; % It is presupposed here that the segmentations times % for a given channel are not decomposed per frames, % because the segmentation of the frame decomposition % is something that does not seem very clear. % Practically, the peak picking for instance is based % therefore on a frame analysis (such as novelty), and % segmentation are inferred between these frames... if size(dsm,2) == 1 dsm = dsm'; end fsk = [fsk dsm]; end end fsk = sort(fsk); % Here is the chronological ordering if isempty(fsk) ffsk = {[0;dtk(end)]}; sxk = {dxk}; stk = {dtk}; n = 1; elseif size(fsk,1) == 1 ffsk = cell(1,length(fsk)+1); ffsk{1} = [dtk(1);fsk(1)]; for h = 1:length(fsk)-1 ffsk{h+1} = [fsk(h);fsk(h+1)]; end ffsk{end} = [fsk(end);dtk(end)]; n = length(ffsk); crd = zeros(1,n+1); % the sample positions of the % segmentations in the channel crd0 = 0; for i = 1:n crd0 = crd0 + find(dtk(crd0+1:end)>=ffsk{i}(1),1); crd(i) = crd0; end crd(n+1) = size(dxk,1)+1; sxk = cell(1,n); % each cell contains a segment stk = cell(1,n); % each cell contains % the corresponding time positions for i = 1:n sxk{i} = dxk(crd(i):crd(i+1)-1,1,:); stk{i} = dtk(crd(i):crd(i+1)-1); end elseif size(fsk,1) == 2 ffsk = cell(1,size(fsk,2)); for h = 1:length(fsk) ffsk{h} = [fsk(1,h);fsk(2,h)]; end n = length(ffsk); crd = zeros(2,n); % the sample positions of the % segmentations in the channel crd0 = 0; for i = 1:n crd0 = crd0 + find(dtk(crd0+1:end)>=ffsk{i}(1),1); crd(i,1) = crd0; crd0 = crd0 + find(dtk(crd0+1:end)>=ffsk{i}(2),1); crd(i,2) = crd0; end sxk = cell(1,n); % each cell contains a segment stk = cell(1,n); % each cell contains % the corresponding time positions for i = 1:n sxk{i} = dxk(crd(i,1):crd(i,2),1,:); stk{i} = dtk(crd(i,1):crd(i,2)); end end sx{k} = sxk; st{k} = stk; fp{k} = ffsk; cl{k} = 1:n; end f = set(x,'Data',sx,'Time',st,'FramePos',fp,'Clusters',cl); p = strat; m = {}; fe = {}; end else [f p] = mirsegment(miraudio(x),varargin{:}); end function p = findsilence(d,fp,throff,thron) d = [0 d 0]; begseg = find(d(1:end-1)<thron & d(2:end)>=thron); nseg = length(begseg); endseg = zeros(1,nseg); removed = []; for i = 1:nseg endseg(i) = begseg(i) + find(d(begseg(i)+1:end)<=throff, 1)-1; if i>1 && endseg(i) == endseg(i-1) removed = [removed i]; end end begseg(removed) = []; %endseg(removed) = []; %endseg(end) = min(endseg(end),length(d)+1); p = fp(1,begseg); %; fp(2,endseg-1)];