Mercurial > hg > smallbox
diff util/classes/dictionaryMatrices/iterativeprojections.m @ 169:290cca7d3469 danieleb
Added dictionary decorrelation functions and test script for ICASSP paper.
| author | Daniele Barchiesi <daniele.barchiesi@eecs.qmul.ac.uk> |
|---|---|
| date | Thu, 29 Sep 2011 09:46:52 +0100 |
| parents | |
| children | 68fb71aa5339 |
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--- /dev/null Thu Jan 01 00:00:00 1970 +0000 +++ b/util/classes/dictionaryMatrices/iterativeprojections.m Thu Sep 29 09:46:52 2011 +0100 @@ -0,0 +1,60 @@ +function [A G res muMin] = grassmannian(n,m,nIter,dd1,dd2,initA,verb) +% grassmanian attempts to create an n by m matrix with minimal mutual +% coherence using an iterative projection method. +% +% [A G res] = grassmanian(n,m,nIter,dd1,dd2,initA) +% +% REFERENCE +% M. Elad, Sparse and Redundant Representations, Springer 2010. + +%% Parameters and Defaults +error(nargchk(2,7,nargin)); + +if ~exist('verb','var') || isempty(verb), verb = false; end %verbose output +if ~exist('initA','var') || isempty(initA), initA = randn(n,m); end %initial matrix +if ~exist('dd2','var') || isempty(dd2), dd2 = 0.99; end %shrinking factor +if ~exist('dd1','var') || isempty(dd1), dd1 = 0.9; end %percentage of coherences to be shrinked +if ~exist('nIter','var') || isempty(nIter), nIter = 10; end %number of iterations + +%% Main algo +A = normc(initA); %normalise columns +[Uinit Sigma] = svd(A); +G = A'*A; %gram matrix + +muMin = sqrt((m-n)/(n*(m-1))); %Lower bound on mutual coherence (equiangular tight frame) +res = zeros(nIter,1); +if verb + fprintf(1,'Iter mu_min mu \n'); +end + +% optimise gram matrix +for iIter = 1:nIter + gg = sort(abs(G(:))); %sort inner products from less to most correlated + pos = find(abs(G(:))>=gg(round(dd1*(m^2-m))) & abs(G(:)-1)>1e-6); %find large elements of gram matrix + G(pos) = G(pos)*dd2; %shrink large elements of gram matrix + [U S V] = svd(G); %compute new SVD of gram matrix + S(n+1:end,1+n:end) = 0; %set small eigenvalues to zero (this ensures rank(G)<=d) + G = U*S*V'; %update gram matrix + G = diag(1./abs(sqrt(diag(G))))*G*diag(1./abs(sqrt(diag(G)))); %normalise gram matrix diagonal + if verb + Geye = G - eye(size(G)); + fprintf(1,'%6i %12.8f %12.8f \n',iIter,muMin,max(abs(Geye(:)))); + end +end + +% [~, Sigma_gram V_gram] = svd(G); %calculate svd decomposition of gramian + +% A = normc(A); %normalise dictionary + +[V_gram Sigma_gram] = svd(G); %calculate svd decomposition of gramian +Sigma_new = sqrt(Sigma_gram(1:n,:)).*sign(Sigma); %calculate singular values of dictionary +A = Uinit*Sigma_new*V_gram'; %update dictionary + +% param.step = 0.01; +% param.reg = 0.01; +% param.nIter = 20; +% A = rotatematrix(initA,A,'linesearchlie',param); + +% %% Debug visualization function +% function plotcart2d(A) +% compass(A(1,:),A(2,:));