Mercurial > hg > camir-aes2014
view toolboxes/distance_learning/mlr/util/rmlr_admm.m @ 0:e9a9cd732c1e tip
first hg version after svn
| author | wolffd |
|---|---|
| date | Tue, 10 Feb 2015 15:05:51 +0000 |
| parents | |
| children |
line wrap: on
line source
function [W, Xi, Diagnostics] = rmlr_admm(C, K, Delta, H, Q, lam) % [W, Xi, D] = mlr_admm(C, Delta, W, X) % % C >= 0 Slack trade-off parameter % K = data matrix (or kernel) % Delta = array of mean margin values % H = structural kernel matrix % Q = kernel-structure interaction vector % % W (output) = the learned metric % Xi = 1-slack % D = diagnostics global DEBUG REG FEASIBLE LOSS INIT STRUCTKERNEL DUALW THRESH; %%% % Initialize the gradient directions for each constraint % global PsiR; global ADMM_Z ADMM_V ADMM_UW ADMM_UV; global ADMM_STEPS; global RHO; numConstraints = length(PsiR); Diagnostics = struct( 'f', [], ... 'num_steps', [], ... 'stop_criteria', []); % Convergence settings if ~isempty(ADMM_STEPS) MAX_ITER = ADMM_STEPS; else MAX_ITER = 10; end ABSTOL = 1e-4 * sqrt(numel(ADMM_Z)); RELTOL = 1e-3; SCALE_THRESH = 10; RHO_RESCALE = 2; stopcriteria= 'MAX STEPS'; % Objective function F = zeros(1,MAX_ITER); % how many constraints alpha = zeros(numConstraints, 1); Gamma = zeros(numConstraints, 1); ln1 = 0; ln2 = 0; % figure(2) % hold off % plot(0) % delete(abc) % delete(abc2) for step = 1:MAX_ITER % do a w-update % dubstep needs: % C <-- static % RHO <-- static % H <-- static % Q <-- static % Delta <-- static % Gamma <-- this one's dynamic for i = 1:numConstraints Gamma(i) = STRUCTKERNEL(ADMM_Z-ADMM_UW, PsiR{i}); end % d = length(K); alpha = mlr_dual(C, RHO, H, Q, Delta, Gamma, alpha); %%% % 3) convert back to W % W = DUALW(alpha, ADMM_Z, ADMM_UW, RHO, K); % figure(1), imagesc(W), drawnow; % Update V ADMM_V = THRESH(ADMM_Z - ADMM_UV, lam/RHO); % Update Z Zold = ADMM_Z; ADMM_Z = FEASIBLE(0.5* (W + ADMM_V + ADMM_UW + ADMM_UV)); % Update residuals ADMM_UW = ADMM_UW + W - ADMM_Z; ADMM_UV = ADMM_UV + ADMM_V - ADMM_Z; % Compute primal objective % slack term Xi = 0; for R = numConstraints:-1:1 Xi = max(Xi, LOSS(ADMM_Z, PsiR{R}, Delta(R), 0)); end F(step) = C * Xi + REG(W, K, 0) + lam * sum(sqrt(sum(W.^2))); % figure(2), loglog(1:step, F(1:step)), xlim([0, MAX_ITER]), drawnow; % Test for convergence %WIP N1 = norm(ADMM_V(:) + W(:) - 2* ADMM_Z(:)); N2 = RHO * norm(2* (Zold(:) - ADMM_Z(:))); eps_primal = ABSTOL + RELTOL * max(norm(W(:)), norm(ADMM_Z(:))); eps_dual = ABSTOL + RELTOL * RHO * norm(ADMM_UW(:)); %end WIP % figure(2), loglog(step + (-1:0), [ln1, N1/eps_primal], 'b'), xlim([0, MAX_ITER]), hold('on'); % figure(2), loglog(step + (-1:0), [ln2, N2/eps_dual], 'r-'), xlim([0, MAX_ITER]), hold('on'), drawnow; % ln1 = N1/eps_primal; % ln2 = N2/eps_dual; if N1 < eps_primal && N2 < eps_dual stopcriteria = 'CONVERGENCE'; break; end if N1 > SCALE_THRESH * N2 dbprint(3, sprintf('RHO: %.2e UP %.2e', RHO, RHO * RHO_RESCALE)); RHO = RHO * RHO_RESCALE; ADMM_UW = ADMM_UW / RHO_RESCALE; elseif N2 > SCALE_THRESH * N1 dbprint(3, sprintf('RHO: %.2e DN %.2e', RHO, RHO / RHO_RESCALE)); RHO = RHO / RHO_RESCALE; ADMM_UW = ADMM_UW * RHO_RESCALE; end end % figure(2), hold('off'); %%% % Ensure feasibility % W = FEASIBLE(W); %%% % Compute the slack % Xi = 0; for R = numConstraints:-1:1 Xi = max(Xi, LOSS(W, PsiR{R}, Delta(R), 0)); end %%% % Update diagnostics % Diagnostics.f = F(1:step)'; Diagnostics.stop_criteria = stopcriteria; Diagnostics.num_steps = step; dbprint(1, '\t%s after %d steps.\n', stopcriteria, step); end function alpha = mlr_dual(C, RHO, H, Q, Delta, Gamma, alpha) global PsiClock; m = length(Delta); if nargin < 7 alpha = zeros(m,1); end %%% % 1) construct the QP parameters % b = RHO * (Gamma - Delta) - Q; %%% % 2) solve the QP % alpha = qplcprog(H, b, ones(1, m), C, [], [], 0, []); %%% % 3) update the Psi clock % PsiClock(alpha > 0) = 0; end