Mercurial > hg > camir-aes2014
view toolboxes/MIRtoolbox1.3.2/MIRToolbox/@mircepstrum/mircepstrum.m @ 0:e9a9cd732c1e tip
first hg version after svn
| author | wolffd |
|---|---|
| date | Tue, 10 Feb 2015 15:05:51 +0000 |
| parents | |
| children |
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function varargout = mircepstrum(orig,varargin) % s = mircepstrum(x) computes the cepstrum, which indicates % periodicities, and is used for instance for pitch detection. % x can be either a spectrum, an audio signal, or the name of an audio file. % Optional parameter: % mircepstrum(...,'Min',min) specifies the lowest delay taken into % consideration, in seconds. % Default value: 0.0002 s (corresponding to a maximum frequency of % 5 kHz). % mircepstrum(...,'Max',max) specifies the highest delay taken into % consideration, in seconds. % Default value: 0.05 s (corresponding to a minimum frequency of % 20 Hz). % mircepstrum(...,'Freq') represents the cepstrum in the frequency % domain. mi.key = 'Min'; mi.type = 'Integer'; mi.default = 0.0002; mi.unit = {'s','Hz'}; mi.defaultunit = 's'; mi.opposite = 'ma'; option.mi = mi; ma.key = 'Max'; ma.type = 'Integer'; ma.default = .05; ma.unit = {'s','Hz'}; ma.defaultunit = 's'; ma.opposite = 'mi'; option.ma = ma; fr.key = 'Freq'; fr.type = 'Boolean'; fr.default = 0; option.fr = fr; complex.key = 'Complex'; complex.type = 'Boolean'; complex.default = 0; option.complex = complex; specif.option = option; specif.defaultframelength = 0.05; specif.defaultframehop = 0.5; varargout = mirfunction(@mircepstrum,orig,varargin,nargout,specif,@init,@main); function [x type] = init(x,option) if not(isamir(x,'mircepstrum')) x = mirspectrum(x); end type = 'mircepstrum'; function c = main(orig,option,postoption) if iscell(orig) orig = orig{1}; end c.phase = []; if isa(orig,'mircepstrum') c.freq = orig.freq; else c.freq = 0; end c = class(c,'mircepstrum',mirdata(orig)); c = purgedata(c); c = set(c,'Title','Cepstrum','Abs','quefrency (s)','Ord','magnitude'); if isa(orig,'mircepstrum') if option.ma < Inf || option.mi > 0 || get(orig,'FreqDomain') mag = get(orig,'Magnitude'); pha = get(orig,'Phase'); que = get(orig,'Quefrency'); for h = 1:length(mag) for k = 1:length(mag{h}) if get(orig,'FreqDomain') mag{h}{k} = flipud(mag{h}{k}); que{h}{k} = flipud(1./que{h}{k}); pha{h}{k} = flipud(pha{h}{k}); end range = find(que{h}{k}(:,1,1) <= option.ma & ... que{h}{k}(:,1,1) >= option.mi); mag{h}{k} = mag{h}{k}(range,:,:); pha{h}{k} = pha{h}{k}(range,:,:); que{h}{k} = que{h}{k}(range,:,:); end end c = set(c,'Magnitude',mag,'Phase',pha,'Quefrency',que,'FreqDomain',0); end c = modif(c,option); elseif isa(orig,'mirspectrum') mag = get(orig,'Magnitude'); pha = get(orig,'Phase'); f = get(orig,'Sampling'); q = cell(1,length(mag)); for h = 1:length(mag) len = ceil(option.ma*f{h}); start = ceil(option.mi*f{h})+1; q{h} = cell(1,length(mag{h})); for k = 1:length(mag{h}) m = mag{h}{k}.*exp(1i*pha{h}{k}); m = [m(1:end-1,:) ; conj(flipud(m))]; % Reconstitution of the complete abs(FFT) if not(option.complex) m = abs(m); end m = log(m); c0=fft(m); q0=repmat((0:(size(c0,1)-1))'/f{k},[1,size(m,2),size(m,3)]); len = min(len,floor(size(c0,1)/2)); mag{h}{k} = abs(c0(start:len,:,:)); if option.complex pha{h}{k} = unwrap(angle(c0(start:len,:,:))); else pha{h}{k} = nan(size(c0(start:len,:,:))); end q{h}{k} = q0(start:len,:,:); end end c = set(c,'Magnitude',mag,'Phase',pha,'Quefrency',q); c = modif(c,option); end function c = modif(c,option) mag = get(c,'Magnitude'); que = get(c,'Quefrency'); if option.fr && not(get(c,'FreqDomain')) for k = 1:length(mag) for l = 1:length(mag{k}) m = mag{k}{l}; q = que{k}{l}; if not(isempty(m)) if q(1,1) == 0 m = m(2:end,:,:); q = q(2:end,:,:); end m = flipud(m); q = flipud(1./q); end mag{k}{l} = m; que{k}{l} = q; end end c = set(c,'FreqDomain',1,'Abs','frequency (Hz)'); end c = set(c,'Magnitude',mag,'Quefrency',que,'Freq');