Mercurial > hg > camir-aes2014
view toolboxes/MIRtoolbox1.3.2/MIRToolbox/mirpulseclarity.m @ 0:e9a9cd732c1e tip
first hg version after svn
| author | wolffd |
|---|---|
| date | Tue, 10 Feb 2015 15:05:51 +0000 |
| parents | |
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function varargout = mirpulseclarity(orig,varargin) % r = mirpulseclarity(x) estimates the rhythmic clarity, indicating the % strength of the beats estimated by the mirtempo function. % Optional arguments: % mirpulseclarity(...,s): specifies a strategy for pulse clarity % estimation. % Possible values: 'MaxAutocor' (default), 'MinAutocor', % 'KurtosisAutocor', MeanPeaksAutocor', 'EntropyAutocor', % 'InterfAutocor', 'TempoAutocor', 'ExtremEnvelop', % 'Attack', 'Articulation' % mirpulseclarity(...,'Frame',l,h): orders a frame decomposition of % the audio input of window length l (in seconds) and hop factor % h, expressed relatively to the window length. % Default values: l = 5 seconds and h = .1 % Onset detection strategies: 'Envelope' (default), 'DiffEnvelope', % 'SpectralFlux', 'Pitch'. % Options related to the autocorrelation computation can be specified % as well: 'Min', 'Max', 'Resonance', 'Enhanced' % Options related to the tempo estimation can be specified here % as well: 'Sum', 'Total', 'Contrast'. % cf. User's Manual for more details. % [r,a] = mirpulseclarity(x) also returns the beat autocorrelation. model.key = 'Model'; model.type = 'Integer'; model.default = 0; option.model = model; stratg.type = 'String'; stratg.choice = {'MaxAutocor','MinAutocor','MeanPeaksAutocor',... 'KurtosisAutocor','EntropyAutocor',... 'InterfAutocor','TempoAutocor','ExtremEnvelop',... 'Attack','Articulation'}; ...,'AttackDiff' stratg.default = 'MaxAutocor'; option.stratg = stratg; frame.key = 'Frame'; frame.type = 'Integer'; frame.number = 2; frame.keydefault = [5 .1]; frame.default = [0 0]; option.frame = frame; %% options related to mironsets: 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 = 'Spectro'; option.envmeth = envmeth; %% options related to 'Filter': ftype.key = 'FilterType'; ftype.type = 'String'; ftype.choice = {'IIR','HalfHann'}; ftype.default = 'IIR'; option.ftype = ftype; fb.key = 'Filterbank'; fb.type = 'Integer'; fb.default = 20; option.fb = fb; fbtype.key = 'FilterbankType'; fbtype.type = 'String'; fbtype.choice = {'Gammatone','Scheirer','Klapuri'}; fbtype.default = 'Scheirer'; option.fbtype = fbtype; %% options related to 'Spectro': band.type = 'String'; band.choice = {'Freq','Mel','Bark','Cents'}; band.default = 'Freq'; option.band = band; 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; aver.key = 'Smooth'; aver.type = 'Integer'; aver.default = 0; aver.keydefault = 30; option.aver = aver; oplog.key = 'Log'; oplog.type = 'Boolean'; oplog.default = 0; option.log = oplog; mu.key = 'Mu'; mu.type = 'Boolean'; mu.default = 1; option.mu = mu; %% options related to 'SpectralFlux' inc.key = 'Inc'; inc.type = 'Boolean'; inc.default = 1; option.inc = inc; median.key = 'Median'; median.type = 'Integer'; median.number = 2; median.default = [0 0]; % Not same default as in mirtempo option.median = median; hw.key = 'Halfwave'; hw.type = 'Boolean'; hw.default = 0; %NaN; %0; % Not same default as in mirtempo option.hw = hw; %% options related to mirattackslope slope.type = 'String'; slope.choice = {'Diff','Gauss'}; slope.default = 'Diff'; option.slope = slope; %% options related to mirautocor: enh.key = 'Enhanced'; enh.type = 'Integers'; enh.default = []; enh.keydefault = 2:10; option.enh = enh; r.key = 'Resonance'; r.type = 'String'; r.choice = {'ToiviainenSnyder','vonNoorden',0,'off','no'}; r.default = 'ToiviainenSnyder'; option.r = r; mi.key = 'Min'; mi.type = 'Integer'; mi.default = 40; option.mi = mi; ma.key = 'Max'; ma.type = 'Integer'; ma.default = 200; option.ma = ma; %% options related to mirtempo: sum.key = 'Sum'; sum.type = 'String'; sum.choice = {'Before','After','Adjacent'}; sum.default = 'Before'; option.sum = sum; m.key = 'Total'; m.type = 'Integer'; m.default = 1; option.m = m; thr.key = 'Contrast'; thr.type = 'Integer'; thr.default = 0.01; % Not same default as in mirtempo option.thr = thr; specif.option = option; varargout = mirfunction(@mirpulseclarity,orig,varargin,nargout,specif,@init,@main); %% Initialisation function [x type] = init(x,option) %if isframed(x) % warning('WARNING IN MIRPULSECLARITY: The input should not be already decomposed into frames.'); % disp(['Suggestion: Use the ''Frame'' option instead.']) %end if iscell(x) x = x{1}; end if isamir(x,'mirautocor') type = {'mirscalar','mirautocor'}; elseif length(option.model) > 1 a = x; type = {'mirscalar'}; for m = 1:length(option.model) if option.frame.length.val y = mirpulseclarity(a,'Model',option.model(m),... 'Frame',option.frame.length.val,... option.frame.length.unit,... option.frame.hop.val,... option.frame.hop.unit); else y = mirpulseclarity(a,'Model',option.model(m)); end if m == 1 x = y; else x = x + y; end end else if option.model switch option.model case 1 case 2 option.envmeth = 'Filter'; option.fbtype = 'Gammatone'; option.mu = 0; option.r = 0; option.lambda = .8; option.sum = 'After'; end end if length(option.stratg)>7 && strcmpi(option.stratg(end-6:end),'Autocor') if (strcmpi(option.stratg,'MaxAutocor') || ... strcmpi(option.stratg,'MinAutocor') || ... strcmpi(option.stratg,'EntropyAutocor')) option.m = 0; end if strcmpi(option.stratg,'MinAutocor') option.enh = 0; end if option.frame.length.val [t,x] = mirtempo(x,option.fea,'Method',option.envmeth,... option.band,... 'Sum',option.sum,'Enhanced',option.enh,... 'Resonance',option.r,'Smooth',option.aver,... 'HalfwaveDiff',option.diffhwr,... 'Lambda',option.lambda,... 'Frame',option.frame.length.val,... option.frame.length.unit,... option.frame.hop.val,... option.frame.hop.unit,... 'FilterbankType',option.fbtype,... 'FilterType',option.ftype,... 'Filterbank',option.fb,'Mu',option.mu,... 'Log',option.log,... 'Inc',option.inc,'Halfwave',option.hw,... 'Median',option.median(1),option.median(2),... 'Min',option.mi,'Max',option.ma,... 'Total',option.m,'Contrast',option.thr); else [t,x] = mirtempo(x,option.fea,'Method',option.envmeth,... option.band,... 'Sum',option.sum,'Enhanced',option.enh,... 'Resonance',option.r,'Smooth',option.aver,... 'HalfwaveDiff',option.diffhwr,... 'Lambda',option.lambda,... 'FilterbankType',option.fbtype,... 'FilterType',option.ftype,... 'Filterbank',option.fb,'Mu',option.mu,... 'Log',option.log,... 'Inc',option.inc,'Halfwave',option.hw,... 'Median',option.median(1),option.median(2),... 'Min',option.mi,'Max',option.ma,... 'Total',option.m,'Contrast',option.thr); end type = {'mirscalar','mirautocor'}; elseif strcmpi(option.stratg,'ExtremEnvelop') x = mironsets(x,'Filterbank',option.fb); type = {'mirscalar','mirenvelope'}; elseif strcmpi(option.stratg,'Attack') x = mirattackslope(x,option.slope); type = {'mirscalar','mirenvelope'}; % elseif strcmpi(option.stratg,'AttackDiff') % type = {'mirscalar','mirenvelope'}; elseif strcmpi(option.stratg,'Articulation') x = mirlowenergy(x,'ASR'); type = {'mirscalar','mirscalar'}; else type = {'mirscalar','miraudio'}; end end %% Main function function o = main(a,option,postoption) if option.model == 2 option.stratg = 'InterfAutocor'; end if isa(a,'mirscalar') && not(strcmpi(option.stratg,'Attack')) % not very nice test... to improve. o = {a}; return end if option.m == 1 && ... (strcmpi(option.stratg,'InterfAutocor') || ... strcmpi(option.stratg,'MeanPeaksAutocor')) option.m = Inf; end if iscell(a) a = a{1}; end if strcmpi(option.stratg,'MaxAutocor') d = get(a,'Data'); rc = mircompute(@max,d); elseif strcmpi(option.stratg,'MinAutocor') d = get(a,'Data'); rc = mircompute(@minusmin,d); elseif strcmpi(option.stratg,'MeanPeaksAutocor') m = get(a,'PeakVal'); rc = mircompute(@meanpeaks,m); elseif strcmpi(option.stratg,'KurtosisAutocor') a = mirpeaks(a,'Extract','Total',option.m,'NoBegin','NoEnd'); k = mirkurtosis(a); %d = get(k,'Data'); %rc = mircompute(@meanpeaks,d); rc = mirmean(k); elseif strcmpi(option.stratg,'EntropyAutocor') rc = mirentropy(a); elseif strcmpi(option.stratg,'InterfAutocor') a = mirpeaks(a,'Total',option.m,'NoBegin','NoEnd'); m = get(a,'PeakVal'); p = get(a,'PeakPosUnit'); rc = mircompute(@interf,m,p); elseif strcmpi(option.stratg,'TempoAutocor') a = mirpeaks(a,'Total',1,'NoBegin','NoEnd'); p = get(a,'PeakPosUnit'); rc = mircompute(@tempo,p); elseif strcmpi(option.stratg,'ExtremEnvelop') a = mirenvelope(a,'Normal'); p = mirpeaks(a,'Order','Abscissa'); p = get(p,'PeakPreciseVal'); n = mirpeaks(a,'Valleys','Order','Abscissa'); n = get(n,'PeakPreciseVal'); rc = mircompute(@shape,p,n); elseif strcmpi(option.stratg,'Attack') rc = mirmean(a); %elseif strcmpi(option.stratg,'AttackDiff') % a = mirpeaks(a); % m = get(a,'PeakVal'); % rc = mircompute(@meanpeaks,m); elseif strcmpi(option.stratg,'Articulation') rc = a; end if iscell(rc) pc = mirscalar(a,'Data',rc,'Title','Pulse clarity'); else pc = set(rc,'Title',['Pulse clarity (',get(rc,'Title'),')']); end if option.model switch option.model case 1 alpha = 0; beta = 2.2015; lambda = .1; case 2 alpha = 0; beta = 3.5982; lambda = 1.87; end if not(lambda == 0) pc = (pc+alpha)^lambda * beta; else pc = log(pc+alpha) * beta; end title = ['Pulse clarity (Model ',num2str(option.model),')']; pc = set(pc,'Title',title); end o = {pc a}; %% Routines function r = shape(p,n) p = p{1}; n = n{1}; if length(p)>length(n) d = sum(p(1:end-1) - n) + sum(p(2:end) - n); r = d/(2*length(n)); elseif length(p)<length(n) d = sum(p - n(1:end-1)) + sum(p - n(2:end)); r = d/(2*length(p)); else d = sum(p(2:end) - n(1:end-1)) + sum(p(1:end-1) - n(2:end)); r = d/(2*(length(p)-1)); end function rc = minusmin(ac) rc = -min(ac); function rc = meanpeaks(ac) rc = zeros(1,length(ac)); for j = 1:length(ac) if isempty(ac{j}) rc(j) = NaN; else rc(j) = mean(ac{j}); end end function rc = interf(mk,pk) rc = zeros(size(mk)); for j = 1:size(mk,3) for i = 1:size(mk,2) pij = pk{1,i,j}; mij = mk{1,i,j}; if isempty(pij) rc(1,i,j) = 0; else high = max(pij(2:end),pij(1)); low = min(pij(2:end),pij(1)); quo = rem(high,low)./low; nomult = quo>.15 & quo<.85; fij = mij(2:end)/mij(1) .*nomult; fij(fij<0) = 0; rc(1,i,j) = exp(-sum(fij)/4); % Pulsations that are not in integer ratio % with dominant pulse decrease clarity end end end function rc = tempo(pk) rc = zeros(size(pk)); for j = 1:size(pk,3) for i = 1:size(pk,2) pij = pk{1,i,j}; if isempty(pij) rc(1,i,j) = 0; else rc(1,i,j) = exp(-pij(1)/4)/exp(-.33/4); % Fast dominant pulse % increases clarity end end end