📄 test_anisotropic_fm.m.svn-base
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% test for a simple anisotropic metric%name = 'fixed-2d';%name = 'fixed-3d';name = 'varying-2d';rep = 'results/anisotropic-fm/';if not(exist(rep)) mkdir(rep);end% create the main direction of the fieldswitch name case 'fixed-3d' % Fixed 3D tensor field n = 20; s = [n n n]; % size % main direction of the tensor u = [1 .1 .1]; U = repmat( reshape(u,1,1,1,3),[n n n 1] ); case 'fixed-2d' % Fixed 2D tensor field n = 40; s = [n n 1]; % main direction of the tensor u = [1 .1]; U = repmat( reshape(u,1,1,2),[n n 1] ); case 'varying-2d' % spacially varying 2D field n = 200; % create 2D vector field s = [n n 1]; randn('seed', 12345); U = randn(n,n,2); sigma = (n/200)*30; options.bound = 'per'; for it=1:10 U = perform_vf_normalization( perform_blurring(U, sigma,options) ); end endU = perform_vf_normalization( U );if exist('perform_lic') && size(U,4)==1 % compute a cool 2D lic texture options.isoriented = 0; M0 = perform_blurring(randn(n),0); M0 = perform_histogram_equalization( M0, 'linear'); options.histogram = 'linear'; options.dt = 0.8; options.M0 = M0; options.verb = 1; options.flow_correction = 1; options.niter_lic = 1; w = 15; w = 30; M = perform_lic(U, w, options); warning off; imwrite( rescale(M), [rep name '-texture.png'], 'png' ); warning on;else M = U; % background imageend% test for various degree of anisotropyaniso_list = [.01 .05 .1 .2 .5 1];%% test for progressive propagationaniso = .01;V = cat(3, -U(:,:,2), U(:,:,1)); % orthogonal vectorT = perform_tensor_recomp(U,V, ones(n),ones(n)*aniso );%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% one starting point and many geodesics on the boundarystart_points = [n;n]/2;% end points on the boundaryt = 1:n;x = [t t*0+n t(end-1:-1:1) t*0+1];y = [t*0+1 t t*0+n t(end-1:-1:1)];npaths = 50;s = round(linspace( 1,length(x), npaths+1) ); s(end) = [];end_points = cat(1, x(s),y(s));ms = 30; lw = 3; % display paramsfor ianiso = 1:length(aniso_list) % build the tensor field aniso = aniso_list(ianiso); V = cat(3, -U(:,:,2), U(:,:,1)); % orthogonal vector T = perform_tensor_recomp(U,V, ones(n),ones(n)*aniso ); % propagation [D,S,Q] = perform_fast_marching(T, start_points); % for sexy display D1 = perform_histogram_equalization(D, linspace(0,1,n^2)); % extract tons of geodesics for i=1:npaths paths{i} = compute_geodesic(D,end_points(:,i), options); end % display clf; hold on; imageplot(D1); axis image; axis off; colormap jet(256); for i=1:npaths end_point = end_points(:,i); h = plot( paths{i}(2,:), paths{i}(1,:), 'k' ); set(h, 'LineWidth', lw); h = plot(end_point(2),end_point(1), '.b'); set(h, 'MarkerSize', ms); end h = plot(start_points(2),start_points(1), '.r'); set(h, 'MarkerSize', ms); hold off; colormap jet(256); axis ij; saveas(gcf, [rep name '-geodesics-' num2str(ianiso) '.png'], 'png');end%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% many starting point and Voronoi diagramsp = 3;x = n/(p*2):n/p:n-n/(p*2);[Y,X] = meshgrid(x,x);start_points = round( start_points*(n-1)+1 );start_points = cat(1, X(:)', Y(:)'); %% progressive propagation[D,S,Q] = perform_fast_marching(T, start_points );dmax_list = linspace( 0,max(D(:)), 15 ); dmax_list(1) = []; % dmax_list(end) = Inf;for i=1:length(dmax_list) options.dmax = dmax_list(i); [D,S,Q] = perform_fast_marching(T, start_points, options); I = find(D~=Inf); J = find(D==Inf); D(I) = perform_histogram_equalization(D(I), linspace(0,1,length(I))); D(J) = 0; A = apply_colormap(D, 'jet'); A(J) = M(J); A(J+n^2) = M(J); A(J+2*n^2) = M(J); warning off; imwrite( A, [rep name '-propagation-' num2str(i) '.png'], 'png' ); warning on; imageplot(A); drawnow;end%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% test for various anisotropynstart = 1;nstart = 40;if nstart==1 start_points = [n/2;n/2];else start_points = rand(2,nstart); start_points(1,:) = rescale(start_points(1,:),.1,.9); start_points(2,:) = rescale(start_points(2,:),.1,.9); p = 8; x = n/(p*2):n/p:n-n/(p*2); [Y,X] = meshgrid(x,x); start_points = round( start_points*(n-1)+1 ); start_points = cat(1, X(:)', Y(:)'); nstart = size(start_points,2); start_points = start_points(:,randperm(nstart));endif strcmp(name(end-1:end), '3d') start_points(end/2) = ceil(s(end)/2); endfor ianiso = 1:length(aniso_list) aniso = aniso_list(ianiso); % use cross product to compute the 2 remaining orthogonal directions if strcmp(name(end-1:end), '2d') % 3D field V = cat(3, -U(:,:,2), U(:,:,1)); % orthogonal vector T = perform_tensor_recomp(U,V, ones(n),ones(n)*aniso ); else % 3D field U = cat(5, U, randn(s(1),s(2),s(3),3,2)); U(:,:,:,:,3) = cross( U(:,:,:,:,1),U(:,:,:,:,2), 4 ); U(:,:,:,:,3) = perform_vf_normalization( U(:,:,:,:,3) ); U(:,:,:,:,2) = cross( U(:,:,:,:,1),U(:,:,:,:,3), 4 ); U(:,:,:,:,2) = perform_vf_normalization( U(:,:,:,:,2) ); Lambda = ones(s(1),s(2),s(3),3); Lambda(:,:,:,2:3) = aniso; T = perform_tensor_decomp_3d(U,Lambda); end [D,S,Q] = perform_fast_marching(T, start_points); D1 = D(:,:,ceil(s(end)/2)); if strcmp(name(end-1:end),'3d') T1 = T(:,:,ceil(s(end)/2), 1:2,1:2); else T1 = T; end D1 = perform_histogram_equalization(D1, linspace(0,1,n^2)); warning off; imwrite( apply_colormap(Q, 'jet'), [rep name '-aniso-' num2str(ianiso) '-voronoi.png'], 'png' ); imwrite( apply_colormap(D1, 'jet'), [rep name '-aniso-' num2str(ianiso) '-distance.png'], 'png' ); warning on; clf; plot_tensor_field(T1,M); saveas(gcf, [rep name '-aniso-' num2str(ianiso) '-tensors.png'], 'png'); clf; %hold on; options.sub = round(n/15);% options.color = 'k';% plot_tensor_field(T1, D1, options); imageplot(D1); h = plot(start_points(2,:),start_points(1,:), 'w.'); set(h, 'MarkerSize', 25); colormap jet(256); % saveas(gcf, [rep name '-aniso-' num2str(ianiso) '.png'], 'png');end⌨️ 快捷键说明
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