Mercurial > hg > smallbox
view examples/SMALL_test_mocod.m @ 188:2f5ce7c8792a danieleb
removed check for wLength as not necessary.
author | daniele@danieleb.com |
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date | Wed, 15 Feb 2012 11:02:45 +0100 |
parents | 0dc98f1c60bb |
children |
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%% SMALL_test_mocod % Script that tests the twostep dictionary learning algorithm with MOCOD % dictionary update. % % REFERENCES % D. Barchiesi and M. D. Plumbely, Learning incoherenct dictionaries for % sparse approximation using iterative projections and rotations. %% Clear and close clc, clear, close all %% Parameteres nTrials = 10; %number of trials of the experiment % Dictionary learning parameters toolbox = 'TwoStepDL'; %dictionary learning toolbox dicUpdate = 'mocod'; %dictionary learning updates zeta = logspace(-2,2,10); %range of values for the incoherence term eta = logspace(-2,2,10); %range of values for the unit norm term iterNum = 20; %number of iterations epsilon = 1e-6; %tolerance level dictSize = 512; %number of atoms in the dictionary percActiveAtoms = 5; %percentage of active atoms % Test signal parameters signal = audio('music03_16kHz.wav'); %audio signal blockSize = 256; %size of audio frames overlap = 0.5; %overlap between consecutive frames % Dependent parameters nActiveAtoms = fix(blockSize/100*percActiveAtoms); %number of active atoms % Initial dictionaries gaborParam = struct('N',blockSize,'redundancyFactor',2,'wd',@rectwin); gaborDict = Gabor_Dictionary(gaborParam); initDicts = {[],gaborDict}; %cell containing initial dictionaries %% Generate audio approximation problem %buffer frames of audio into columns of the matrix S signal = buffer(signal,blockSize,blockSize*overlap,@rectwin); SMALL.Problem.b = signal.S; %copy signals from training set b to test set b1 (needed for later functions) SMALL.Problem.b1 = SMALL.Problem.b; %omp2 sparse representation solver ompParam = struct('X',SMALL.Problem.b,... 'epsilon',epsilon,... 'maxatoms',nActiveAtoms); %parameters solver = SMALL_init_solver('ompbox','omp2',ompParam,false); %solver structure %% Test nInitDicts = length(initDicts);%number of initial dictionaries nZetas = length(zeta); %number of incoherence penalty parameters nEtas = length(eta); %number of unit norm penalty parameters %create dictionary learning structures SMALL.DL(nTrials,nInitDicts,nZetas,nEtas) = SMALL_init_DL(toolbox); for iTrial=1:nTrials for iInitDicts=1:nInitDicts for iZetas=1:nZetas for iEtas=1:nEtas SMALL.DL(iTrial,iInitDicts,iZetas,iEtas).toolbox = toolbox; SMALL.DL(iTrial,iInitDicts,iZetas,iEtas).name = dicUpdate; SMALL.DL(iTrial,iInitDicts,iZetas,iEtas).profile = true; SMALL.DL(iTrial,iInitDicts,iZetas,iEtas).param = ... struct('data',SMALL.Problem.b,... %observed data 'Tdata',nActiveAtoms,... %active atoms 'dictsize',dictSize,... %number of atoms 'iternum',iterNum,... %number of iterations 'memusage','high',... %memory usage 'solver',solver,... %sparse approx solver 'initdict',initDicts(iInitDicts),...%initial dictionary 'zeta',zeta(iZetas),... %incoherence penalty factor 'eta',eta(iEtas)); %unit norm penalty factor %learn dictionary SMALL.DL(iTrial,iInitDicts,iZetas,iEtas) = ... SMALL_learn(SMALL.Problem,SMALL.DL(iTrial,iInitDicts,iZetas,iEtas)); end end end end %% Evaluate coherence and snr of representation sr = zeros(size(SMALL.DL)); %signal to noise ratio mu = zeros(iTrial,iInitDicts,iZetas,iEtas); %coherence dic(size(SMALL.DL)) = dictionary; %initialise dictionary objects for iTrial=1:nTrials for iInitDicts=1:nInitDicts for iZetas=1:nZetas for iEtas=1:nEtas %Sparse representation SMALL.Problem.A = SMALL.DL(iTrial,iInitDicts,iZetas,iEtas).D; tempSolver = SMALL_solve(SMALL.Problem,solver); %calculate snr sr(iTrial,iInitDicts,iZetas,iEtas) = ... snr(SMALL.Problem.b,... SMALL.DL(iTrial,iInitDicts,iZetas,iEtas).D*tempSolver.solution); %calculate mu dic(iTrial,iInitDicts,iZetas,iEtas) = ... dictionary(SMALL.DL(iTrial,iInitDicts,iZetas,iEtas).D); mu(iTrial,iInitDicts,iZetas,iEtas) = ... dic(iTrial,iInitDicts,iZetas,iEtas).coherence; end end end end %% Plot results minMu = sqrt((dictSize-blockSize)/(blockSize*(dictSize-1)));%lower bound on coherence initDictsNames = {'Data','Gabor'}; %names of initial dictionaries lineStyles = {'k.-','r*-','b+-'}; for iInitDict=1:nInitDicts figure, hold on, grid on %print initial dictionary as figure title DisplayFigureTitle([initDictsNames{iInitDict} ' Initialisation']); % set(gcf,'Units','Normalized'); % txh = annotation(gcf,'textbox',[0.4,0.95,0.2,0.05]); % set(txh,'String',[initDictsNames{iInitDict} ' Initialisation'],... % 'LineStyle','none','HorizontalAlignment','center'); %calculate mean coherence levels and SNRs over trials coherenceLevels = squeeze(mean(mu(:,iInitDict,:,:),1)); meanSNRs = squeeze(mean(sr(:,iInitDict,:,:),1)); % stdSNRs = squeeze(std(sr(:,iInitDict,iZetas,iEtas),0,1)); %plot coherence levels subplot(2,2,1) surf(eta,zeta,coherenceLevels); set(gca,'Xscale','log','Yscale','log','ZLim',[0 1.4]); view(gca,130,20) xlabel('\eta'); ylabel('\zeta'); zlabel('\mu'); title('Coherence') %plot SNRs subplot(2,2,2) surf(eta,zeta,meanSNRs); set(gca,'Xscale','log','Yscale','log','ZLim',[0 25]); view(gca,130,20) xlabel('\eta'); ylabel('\zeta'); zlabel('SNR (dB)'); title('Reconstruction Error') %plot mu/SNR scatter subplot(2,2,[3 4]) mus = mu(:,iInitDict,:,:); mus = mus(:); SNRs = sr(:,iInitDict,:,:); SNRs = SNRs(:); [un idx] = sort(mus); plot([1 1],[0 25],'k') hold on, grid on scatter(mus(idx),SNRs(idx),'k+'); plot([minMu minMu],[0 25],'k--') set(gca,'YLim',[0 25],'XLim',[0 1.4]); xlabel('\mu'); ylabel('SNR (dB)'); legend([{'\mu_{max}'},'MOCOD',{'\mu_{min}'}]); title('Coherence-Reconstruction Error Tradeoff') % plot([minMu minMu],[0 25],'k--') % % set(gca,'YLim',[0 25],'XLim',[0 1.4]); % legend([{'\mu_{max}'},dicDecorrNames,{'\mu_{min}'}]); % xlabel('\mu'); % ylabel('SNR (dB)'); end