Mercurial > hg > smallbox
view examples/SMALL_DL_test.m @ 199:751fa3bddd30 luisf_dev
Added config file for SMALL_solve (removed the if/else code from SMALL_solve); added headers to both config files;
author | luisf <luis.figueira@eecs.qmul.ac.uk> |
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date | Tue, 20 Mar 2012 14:28:51 +0000 |
parents | d50f5bdbe14c |
children | fd0b5d36f6ad |
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function SMALL_DL_test clear, clc, close all % Create a 2-dimensional dataset of points that are oriented in 3 % directions on a x/y plane % % Centre for Digital Music, Queen Mary, University of London. % This file copyright 2012 Daniele Barchiesi. % % This program is free software; you can redistribute it and/or % modify it under the terms of the GNU General Public License as % published by the Free Software Foundation; either version 2 of the % License, or (at your option) any later version. See the file % COPYING included with this distribution for more information. nData = 10000; %number of data theta = [pi/6 pi/3 4*pi/6]; %angles nAngles = length(theta); %number of angles Q = [cos(theta); sin(theta)]; %rotation matrix X = Q*randmog(nAngles,nData); %training data % find principal directions using PCA XXt = X*X'; %cross correlation matrix [U ~] = svd(XXt); %svd of XXt scale = 3; %scale factor for plots subplot(1,2,1), hold on title('Principal Component Analysis') scatter(X(1,:), X(2,:),'.'); %scatter training data O = zeros(size(U)); %origin quiver(O(1,1:2),O(2,1:2),scale*U(1,:),scale*U(2,:),... 'LineWidth',2,'Color','k') %plot atoms axis equal %scale axis subplot(1,2,2), hold on title('K-SVD Dictionary') scatter(X(1,:), X(2,:),'.'); axis equal nAtoms = 3; %number of atoms in the dictionary nIter = 1; %number of dictionary learning iterations initDict = normc(randn(2,nAtoms)); %random initial dictionary O = zeros(size(initDict)); %origin % apply dictionary learning algorithm ksvd_params = struct('data',X,... %training data 'Tdata',1,... %sparsity level 'dictsize',nAtoms,... %number of atoms 'initdict',initDict,...%initial dictionary 'iternum',10); %number of iterations DL = SMALL_init_DL('ksvd','ksvd',ksvd_params); %dictionary learning structure DL.D = initDict; %copy initial dictionary in solution variable problem = struct('b',X); %copy training data in problem structure xdata = DL.D(1,:); ydata = DL.D(2,:); qPlot = quiver(O(1,:),O(2,:),scale*initDict(1,:),scale*initDict(2,:),... 'LineWidth',2,'Color','k','UDataSource','xdata','VDataSource','ydata'); for iIter=1:nIter DL.ksvd_params.initdict = DL.D; pause DL = SMALL_learn(problem,DL); %learn dictionary xdata = scale*DL.D(1,:); ydata = scale*DL.D(2,:); refreshdata(gcf,'caller'); end function X = randmog(m, n) % RANDMOG - Generate mixture of Gaussians s = [0.2 2]; % Choose which Gaussian G1 = (rand(m, n) < 0.9); % Make them X = (G1.*s(1) + (1-G1).*s(2)) .* randn(m,n);