Mercurial > hg > camir-aes2014
view toolboxes/MIRtoolbox1.3.2/MIRToolbox/mirtempo.m @ 0:e9a9cd732c1e tip
first hg version after svn
| author | wolffd |
|---|---|
| date | Tue, 10 Feb 2015 15:05:51 +0000 |
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function varargout = mirtempo(x,varargin) % t = mirtempo(x) evaluates the tempo in beats per minute (BPM). % Optional arguments: % mirtempo(...,'Total',m) selects not only the best tempo, but the m % best tempos. % mirtempo(...,'Frame',l,h) orders a frame decomposition of window % length l (in seconds) and hop factor h, expressed relatively to % the window length. For instance h = 1 indicates no overlap. % Default values: l = 3 seconds and h = .1 % mirtempo(...,'Min',mi) indicates the lowest tempo taken into % consideration, expressed in bpm. % Default value: 40 bpm. % mirtempo(...,'Max',ma) indicates the highest tempo taken into % consideration, expressed in bpm. % Default value: 200 bpm. % mirtempo(...,s) selects the tempo estimation strategy: % s = 'Autocor': Approach based on the computation of the % autocorrelation. (Default strategy) % Option associated to the mirautocor function can be % passed here as well (see help mirautocor): % 'Enhanced' (toggled on by default here) % s = 'Spectrum': Approach based on the computation of the % spectrum . % Option associated to the mirspectrum function can be % passed here as well (see help mirspectrum): % 'ZeroPad' (set by default to 10000 samples) % 'Prod' (toggled off by default) % These two strategies can be combined: the autocorrelation % function is translated into the frequency domain in order % to be compared to the spectrum curve. % tempo(...,'Autocor','Spectrum') multiplies the two curves. % Alternatively, an autocorrelation function ac or a spectrum sp % can be directly passed to the function tempo: % mirtempo(ac) or mirtempo(sp) % The options related to the onset detection phase can be specified % here as well (see help mironsets): % onset detection strategies: 'Envelope', 'DiffEnvelope' % (corresponding to 'Envelope', 'Diff'), 'SpectralFlux, % 'Pitch', 'Log', 'Mu', 'Filterbank' % mironsets(...,'Sum',w) specifies when to sum the channels. % Possible values: % w = 'Before': sum before the autocorrelation or % spectrum computation. % w = 'After': autocorrelation or spectrum computed % for each band, and summed into a "summary". % mirenvelope options: 'HalfwaveCenter','Diff' (toggled on by % default here),'HalfwaveDiff','Center','Smooth', % 'Sampling' % mirflux options: 'Inc','Halfwave','Complex','Median' % mirtempo(...,'Resonance',r) specifies the resonance curve, which % emphasizes the periods that are more easily perceived. % Possible values: 'ToiviainenSnyder' (default), 0 (toggled off) % Optional arguments used for the peak picking (cf. help mirpeaks) % mirtempo(...,'Contrast',thr): a threshold value. A given local % maximum will be considered as a peak if its distance with the % previous and successive local minima (if any) is higher than % this threshold. This distance is expressed with respect to the % total amplitude of the autocorrelation function. % if no value for thr is given, the value thr=0.1 is chosen % by default. % % [t,p] = mirtempo(...) also displays the result of the signal analysis % leading to the tempo estimation, and shows in particular the % peaks corresponding to the tempo values. sum.key = 'Sum'; sum.type = 'String'; sum.choice = {'Before','After','Adjacent',0}; sum.default = 'Before'; option.sum = sum; %% options related to mironsets: frame.key = 'Frame'; frame.type = 'Integer'; frame.number = 2; frame.default = [0 0]; frame.keydefault = [3 .1]; option.frame = frame; fea.type = 'String'; fea.choice = {'Envelope','DiffEnvelope','SpectralFlux','Pitch'}; fea.default = 'Envelope'; option.fea = fea; %% options related to 'Envelope': envmeth.key = 'Method'; envmeth.type = 'String'; envmeth.choice = {'Filter','Spectro'}; envmeth.default = 'Filter'; option.envmeth = envmeth; %% options related to 'Filter': fb.key = 'Filterbank'; fb.type = 'Integer'; fb.default = 10; option.fb = fb; fbtype.key = 'FilterbankType'; fbtype.type = 'String'; fbtype.choice = {'Gammatone','Scheirer','Klapuri'}; fbtype.default = 'Gammatone'; option.fbtype = fbtype; ftype.key = 'FilterType'; ftype.type = 'String'; ftype.choice = {'IIR','HalfHann'}; ftype.default = 'IIR'; option.ftype = ftype; %% options related to 'Spectro': band.type = 'String'; band.choice = {'Freq','Mel','Bark','Cents'}; band.default = 'Freq'; option.band = band; chwr.key = 'HalfwaveCenter'; chwr.type = 'Boolean'; chwr.default = 0; option.chwr = chwr; diff.key = 'Diff'; diff.type = 'Boolean'; diff.default = 1; % Different default for mirtempo option.diff = diff; diffhwr.key = 'HalfwaveDiff'; diffhwr.type = 'Integer'; diffhwr.default = 0; diffhwr.keydefault = 1; option.diffhwr = diffhwr; lambda.key = 'Lambda'; lambda.type = 'Integer'; lambda.default = 1; option.lambda = lambda; mu.key = 'Mu'; mu.type = 'Boolean'; mu.default = 0; option.mu = mu; log.key = 'Log'; log.type = 'Boolean'; log.default = 0; option.log = log; c.key = 'Center'; c.type = 'Boolean'; c.default = 0; option.c = c; aver.key = 'Smooth'; aver.type = 'Integer'; aver.default = 0; aver.keydefault = 30; option.aver = aver; sampling.key = 'Sampling'; sampling.type = 'Integer'; sampling.default = 0; option.sampling = sampling; %% options related to 'SpectralFlux' complex.key = 'Complex'; complex.type = 'Boolean'; complex.default = 0; option.complex = complex; inc.key = 'Inc'; inc.type = 'Boolean'; inc.default = 1; option.inc = inc; median.key = 'Median'; median.type = 'Integer'; median.number = 2; median.default = [.2 1.3]; option.median = median; hw.key = 'Halfwave'; hw.type = 'Boolean'; hw.default = 1; option.hw = hw; %% options related to mirautocor: aut.key = 'Autocor'; aut.type = 'Integer'; aut.default = 0; aut.keydefault = 1; option.aut = aut; nw.key = 'NormalWindow'; nw.default = 0; option.nw = nw; enh.key = 'Enhanced'; enh.type = 'Integers'; enh.default = 2:10; enh.keydefault = 2:10; option.enh = enh; r.key = 'Resonance'; r.type = 'String'; r.choice = {'ToiviainenSnyder','vanNoorden',0,'off','no'}; r.default = 'ToiviainenSnyder'; option.r = r; %% options related to mirspectrum: spe.key = 'Spectrum'; spe.type = 'Integer'; spe.default = 0; spe.keydefault = 1; option.spe = spe; zp.key = 'ZeroPad'; zp.type = 'Integer'; zp.default = 10000; zp.keydefault = Inf; option.zp = zp; prod.key = 'Prod'; prod.type = 'Integers'; prod.default = 0; prod.keydefault = 2:6; option.prod = prod; %% options related to the peak detection m.key = 'Total'; m.type = 'Integer'; m.default = 1; option.m = m; thr.key = 'Contrast'; thr.type = 'Integer'; thr.default = 0.1; option.thr = thr; mi.key = 'Min'; mi.type = 'Integer'; mi.default = 40; option.mi = mi; ma.key = 'Max'; ma.type = 'Integer'; ma.default = 200; option.ma = ma; track.key = 'Track'; track.type = 'Boolean'; track.default = 0; option.track = track; pref.key = 'Pref'; pref.type = 'Integer'; pref.number = 2; pref.default = [0 .2]; option.pref = pref; perio.key = 'Periodicity'; perio.type = 'Boolean'; perio.default = 0; option.perio = perio; specif.option = option; varargout = mirfunction(@mirtempo,x,varargin,nargout,specif,@init,@main); %% INIT function [y type] = init(x,option) if iscell(x) x = x{1}; end if option.perio option.m = 3; option.enh = 2:10; end if not(isamir(x,'mirautocor')) && not(isamir(x,'mirspectrum')) if isframed(x) && strcmpi(option.fea,'Envelope') && not(isamir(x,'mirscalar')) warning('WARNING IN MIRTEMPO: The input should not be already decomposed into frames.'); disp(['Suggestion: Use the ''Frame'' option instead.']) end if strcmpi(option.sum,'Before') optionsum = 1; elseif strcmpi(option.sum,'Adjacent') optionsum = 5; else optionsum = 0; end if option.frame.length.val x = mironsets(x,option.fea,'Filterbank',option.fb,... 'FilterbankType',option.fbtype,... 'FilterType',option.ftype,... 'Sum',optionsum,'Method',option.envmeth,... option.band,'Center',option.c,... 'HalfwaveCenter',option.chwr,'Diff',option.diff,... 'HalfwaveDiff',option.diffhwr,'Lambda',option.lambda,... 'Smooth',option.aver,'Sampling',option.sampling,... 'Complex',option.complex,'Inc',option.inc,... 'Median',option.median(1),option.median(2),... 'Halfwave',option.hw,'Detect',0,... 'Mu',option.mu,'Log',option.log,... 'Frame',option.frame.length.val,... option.frame.length.unit,... option.frame.hop.val,... option.frame.hop.unit); else x = mironsets(x,option.fea,'Filterbank',option.fb,... 'FilterbankType',option.fbtype,... 'FilterType',option.ftype,... 'Sum',optionsum,'Method',option.envmeth,... option.band,'Center',option.c,... 'HalfwaveCenter',option.chwr,'Diff',option.diff,... 'HalfwaveDiff',option.diffhwr,'Lambda',option.lambda,... 'Smooth',option.aver,'Sampling',option.sampling,... 'Complex',option.complex,'Inc',option.inc,... 'Median',option.median(1),option.median(2),... 'Halfwave',option.hw,'Detect',0,... 'Mu',option.mu,'Log',option.log); end end if option.aut == 0 && option.spe == 0 option.aut = 1; end if isamir(x,'mirautocor') || (option.aut && not(option.spe)) y = mirautocor(x,'Min',60/option.ma,'Max',60/option.mi,... 'Enhanced',option.enh,...'NormalInput','coeff',... 'Resonance',option.r,'NormalWindow',option.nw); elseif isamir(x,'mirspectrum') || (option.spe && not(option.aut)) y = mirspectrum(x,'Min',option.mi/60,'Max',option.ma/60,... 'Prod',option.prod,...'NormalInput',... 'ZeroPad',option.zp,'Resonance',option.r); elseif option.spe && option.aut ac = mirautocor(x,'Min',60/option.ma,'Max',60/option.mi,... 'Enhanced',option.enh,...'NormalInput','coeff',... 'Resonance',option.r); sp = mirspectrum(x,'Min',option.mi/60,'Max',option.ma/60,... 'Prod',option.prod,...'NormalInput',... 'ZeroPad',option.zp,'Resonance',option.r); y = ac*sp; end if ischar(option.sum) y = mirsum(y); end y = mirpeaks(y,'Total',option.m,'Track',option.track,... 'Pref',option.pref(1),option.pref(2),... 'Contrast',option.thr,'NoBegin','NoEnd',... 'Normalize','Local'); type = {'mirscalar',mirtype(y)}; %% MAIN function o = main(p,option,postoption) if iscell(p) p = p{1}; end pt = get(p,'TrackPrecisePos'); track = 1; if isempty(pt) || isempty(pt{1}) pt = get(p,'PeakPrecisePos'); track = 0; end bpm = cell(1,length(pt)); for j = 1:length(pt) bpm{j} = cell(1,length(pt{j})); for k = 1:length(pt{j}) ptk = pt{j}{k}; bpmk = cell(1,size(ptk,2)); for h = 1:size(ptk,3) for l = 1:size(ptk,2) ptl = ptk{1,l,h}; if isempty(ptl) bpmk{1,l,h} = NaN; else if isa(p,'mirautocor') && not(get(p,'FreqDomain')) bpmk{1,l,h} = 60./ptl; else bpmk{1,l,h} = ptl*60; end end end end if track bpmk = bpmk{1}; end bpm{j}{k} = bpmk; end end t = mirscalar(p,'Data',bpm,'Title','Tempo','Unit','bpm'); o = {t,p};