Mercurial > hg > camir-aes2014
view toolboxes/FullBNT-1.0.7/netlab3.3/glmtrain.m @ 0:e9a9cd732c1e tip
first hg version after svn
| author | wolffd |
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| date | Tue, 10 Feb 2015 15:05:51 +0000 |
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function [net, options] = glmtrain(net, options, x, t) %GLMTRAIN Specialised training of generalized linear model % % Description % NET = GLMTRAIN(NET, OPTIONS, X, T) uses the iterative reweighted % least squares (IRLS) algorithm to set the weights in the generalized % linear model structure NET. This is a more efficient alternative to % using GLMERR and GLMGRAD and a non-linear optimisation routine % through NETOPT. Note that for linear outputs, a single pass through % the algorithm is all that is required, since the error function is % quadratic in the weights. The algorithm also handles scalar ALPHA % and BETA terms. If you want to use more complicated priors, you % should use general-purpose non-linear optimisation algorithms. % % For logistic and softmax outputs, general priors can be handled, % although this requires the pseudo-inverse of the Hessian, giving up % the better conditioning and some of the speed advantage of the normal % form equations. % % The error function value at the final set of weights is returned in % OPTIONS(8). Each row of X corresponds to one input vector and each % row of T corresponds to one target vector. % % The optional parameters have the following interpretations. % % OPTIONS(1) is set to 1 to display error values during training. If % OPTIONS(1) is set to 0, then only warning messages are displayed. If % OPTIONS(1) is -1, then nothing is displayed. % % OPTIONS(2) is a measure of the precision required for the value of % the weights W at the solution. % % OPTIONS(3) is a measure of the precision required of the objective % function at the solution. Both this and the previous condition must % be satisfied for termination. % % OPTIONS(5) is set to 1 if an approximation to the Hessian (which % assumes that all outputs are independent) is used for softmax % outputs. With the default value of 0 the exact Hessian (which is more % expensive to compute) is used. % % OPTIONS(14) is the maximum number of iterations for the IRLS % algorithm; default 100. % % See also % GLM, GLMERR, GLMGRAD % % Copyright (c) Ian T Nabney (1996-2001) % Check arguments for consistency errstring = consist(net, 'glm', x, t); if ~errstring error(errstring); end if(~options(14)) options(14) = 100; end display = options(1); % Do we need to test for termination? test = (options(2) | options(3)); ndata = size(x, 1); % Add a column of ones for the bias inputs = [x ones(ndata, 1)]; % Linear outputs are a special case as they can be found in one step if strcmp(net.outfn, 'linear') if ~isfield(net, 'alpha') % Solve for the weights and biases using left matrix divide temp = inputs\t; elseif size(net.alpha == [1 1]) if isfield(net, 'beta') beta = net.beta; else beta = 1.0; end % Use normal form equation hessian = beta*(inputs'*inputs) + net.alpha*eye(net.nin+1); temp = pinv(hessian)*(beta*(inputs'*t)); else error('Only scalar alpha allowed'); end net.w1 = temp(1:net.nin, :); net.b1 = temp(net.nin+1, :); % Store error value in options vector options(8) = glmerr(net, x, t); return; end % Otherwise need to use iterative reweighted least squares e = ones(1, net.nin+1); for n = 1:options(14) switch net.outfn case 'logistic' if n == 1 % Initialise model p = (t+0.5)/2; act = log(p./(1-p)); wold = glmpak(net); end link_deriv = p.*(1-p); weights = sqrt(link_deriv); % sqrt of weights if (min(min(weights)) < eps) warning('ill-conditioned weights in glmtrain') return end z = act + (t-p)./link_deriv; if ~isfield(net, 'alpha') % Treat each output independently with relevant set of weights for j = 1:net.nout indep = inputs.*(weights(:,j)*e); dep = z(:,j).*weights(:,j); temp = indep\dep; net.w1(:,j) = temp(1:net.nin); net.b1(j) = temp(net.nin+1); end else gradient = glmgrad(net, x, t); Hessian = glmhess(net, x, t); deltaw = -gradient*pinv(Hessian); w = wold + deltaw; net = glmunpak(net, w); end [err, edata, eprior, p, act] = glmerr(net, x, t); if n == 1 errold = err; wold = netpak(net); else w = netpak(net); end case 'softmax' if n == 1 % Initialise model: ensure that row sum of p is one no matter % how many classes there are p = (t + (1/size(t, 2)))/2; act = log(p./(1-p)); end if options(5) == 1 | n == 1 link_deriv = p.*(1-p); weights = sqrt(link_deriv); % sqrt of weights if (min(min(weights)) < eps) warning('ill-conditioned weights in glmtrain') return end z = act + (t-p)./link_deriv; % Treat each output independently with relevant set of weights for j = 1:net.nout indep = inputs.*(weights(:,j)*e); dep = z(:,j).*weights(:,j); temp = indep\dep; net.w1(:,j) = temp(1:net.nin); net.b1(j) = temp(net.nin+1); end [err, edata, eprior, p, act] = glmerr(net, x, t); if n == 1 errold = err; wold = netpak(net); else w = netpak(net); end else % Exact method of calculation after w first initialised % Start by working out Hessian Hessian = glmhess(net, x, t); gradient = glmgrad(net, x, t); % Now compute modification to weights deltaw = -gradient*pinv(Hessian); w = wold + deltaw; net = glmunpak(net, w); [err, edata, eprior, p] = glmerr(net, x, t); end otherwise error(['Unknown activation function ', net.outfn]); end if options(1) fprintf(1, 'Cycle %4d Error %11.6f\n', n, err) end % Test for termination % Terminate if error increases if err > errold errold = err; w = wold; options(8) = err; fprintf(1, 'Error has increased: terminating\n') return; end if test & n > 1 if (max(abs(w - wold)) < options(2) & abs(err-errold) < options(3)) options(8) = err; return; else errold = err; wold = w; end end end options(8) = err; if (options(1) >= 0) disp(maxitmess); end