Mercurial > hg > camir-aes2014

view toolboxes/FullBNT-1.0.7/bnt/CPDs/@gaussian_CPD/Old/maximize_params.m @ 0:e9a9cd732c1e tip

Find changesets by keywords (author, files, the commit message), revision number or hash, or revset expression.
first hg version after svn
author wolffd
date Tue, 10 Feb 2015 15:05:51 +0000
parents
children
line wrap: on
line source
function CPD = maximize_params(CPD, temp)
% MAXIMIZE_PARAMS Set the params of a CPD to their ML values (Gaussian)
% CPD = maximize_params(CPD, temperature)
%
% Temperature is currently only used for entropic prior on Sigma

% For details, see "Fitting a Conditional Gaussian Distribution", Kevin Murphy, tech. report,
% 1998, available at www.cs.berkeley.edu/~murphyk/papers.html
% Refering to table 2, we use equations 1/2 to estimate the covariance matrix in the untied/tied case,
% and equation 9 to estimate the weight matrix and mean.
% We do not implement spherical Gaussians - the code is already pretty complicated!

if ~adjustable_CPD(CPD), return; end

%assert(approxeq(CPD.nsamples, sum(CPD.Wsum)));
assert(~any(isnan(CPD.WXXsum)))
assert(~any(isnan(CPD.WXYsum)))
assert(~any(isnan(CPD.WYYsum)))

[self_size cpsize dpsize] = size(CPD.weights);

% Append 1s to the parents, and derive the corresponding cross products.
% This is used when estimate the means and weights simultaneosuly,
% and when estimatting Sigma.
% Let x2 = [x 1]'
XY = zeros(cpsize+1, self_size, dpsize); % XY(:,:,i) = sum_l w(l,i) x2(l) y(l)' 
XX = zeros(cpsize+1, cpsize+1, dpsize); % XX(:,:,i) = sum_l w(l,i) x2(l) x2(l)' 
YY = zeros(self_size, self_size, dpsize); % YY(:,:,i) = sum_l w(l,i) y(l) y(l)' 
for i=1:dpsize
  XY(:,:,i) = [CPD.WXYsum(:,:,i) % X*Y
	       CPD.WYsum(:,i)']; % 1*Y
  % [x  * [x' 1]  = [xx' x
  %  1]              x'  1]
  XX(:,:,i) = [CPD.WXXsum(:,:,i) CPD.WXsum(:,i);
	       CPD.WXsum(:,i)'   CPD.Wsum(i)];
  YY(:,:,i) = CPD.WYYsum(:,:,i);
end

w = CPD.Wsum(:);
% Set any zeros to one before dividing
% This is valid because w(i)=0 => WYsum(:,i)=0, etc
w = w + (w==0);

if CPD.clamped_mean
  % Estimating B2 and then setting the last column (the mean) to the clamped mean is *not* equivalent
  % to estimating B and then adding the clamped_mean to the last column.
  if ~CPD.clamped_weights
    B = zeros(self_size, cpsize, dpsize);
    for i=1:dpsize
      if det(CPD.WXXsum(:,:,i))==0
	B(:,:,i) = 0;
      else
	% Eqn 9 in table 2 of TR
	%B(:,:,i) = CPD.WXYsum(:,:,i)' * inv(CPD.WXXsum(:,:,i));
	B(:,:,i) = (CPD.WXXsum(:,:,i) \ CPD.WXYsum(:,:,i))';
      end
    end
    %CPD.weights = reshape(B, [self_size cpsize dpsize]);
    CPD.weights = B;
  end
elseif CPD.clamped_weights % KPM 1/25/02
  if ~CPD.clamped_mean % ML estimate is just sample mean of the residuals
    for i=1:dpsize
      CPD.mean(:,i) = (CPD.WYsum(:,i) - CPD.weights(:,:,i) * CPD.WXsum(:,i)) / w(i);
    end
  end
else % nothing is clamped, so estimate mean and weights simultaneously
  B2 = zeros(self_size, cpsize+1, dpsize);
  for i=1:dpsize
    if det(XX(:,:,i))==0  % fix by U. Sondhauss 6/27/99
      B2(:,:,i)=0;          
    else                    
      % Eqn 9 in table 2 of TR
      %B2(:,:,i) = XY(:,:,i)' * inv(XX(:,:,i));
      B2(:,:,i) = (XX(:,:,i) \ XY(:,:,i))';
    end                   
    CPD.mean(:,i) = B2(:,cpsize+1,i);
    CPD.weights(:,:,i) = B2(:,1:cpsize,i);
  end
end

% Let B2 = [W mu]
if cpsize>0
  B2(:,1:cpsize,:) = reshape(CPD.weights, [self_size cpsize dpsize]);
end
B2(:,cpsize+1,:) = reshape(CPD.mean, [self_size dpsize]);

% To avoid singular covariance matrices,
% we use the regularization method suggested in "A Quasi-Bayesian approach to estimating
% parameters for mixtures of normal distributions", Hamilton 91.
% If the ML estimate is Sigma = M/N, the MAP estimate is (M+gamma*I) / (N+gamma),
% where gamma >=0 is a smoothing parameter (equivalent sample size of I prior)

gamma = CPD.cov_prior_weight;

if ~CPD.clamped_cov
  if CPD.cov_prior_entropic % eqn 12 of Brand AI/Stat 99
    Z = 1-temp;
    % When temp > 1, Z is negative, so we are dividing by a smaller
    % number, ie. increasing the variance.
  else
    Z = 0;
  end
  if CPD.tied_cov
    S = zeros(self_size, self_size);
    % Eqn 2 from table 2 in TR
    for i=1:dpsize
      S = S + (YY(:,:,i) - B2(:,:,i)*XY(:,:,i));
    end
    %denom = max(1, CPD.nsamples + gamma + Z);
    denom = CPD.nsamples + gamma + Z;
    S = (S + gamma*eye(self_size)) / denom;
    if strcmp(CPD.cov_type, 'diag')
      S = diag(diag(S));
    end
    CPD.cov = repmat(S, [1 1 dpsize]);
  else 
    for i=1:dpsize      
      % Eqn 1 from table 2 in TR
      S = YY(:,:,i) - B2(:,:,i)*XY(:,:,i);
      %denom = max(1, w(i) + gamma + Z); % gives wrong answers on mhmm1
      denom = w(i) + gamma + Z;
      S = (S + gamma*eye(self_size)) / denom;
      CPD.cov(:,:,i) = S;
    end
    if strcmp(CPD.cov_type, 'diag')
      for i=1:dpsize      
	CPD.cov(:,:,i) = diag(diag(CPD.cov(:,:,i)));
      end
    end
  end
end


check_covars = 0;
min_covar = 1e-5;
if check_covars % prevent collapsing to a point
  for i=1:dpsize
    if min(svd(CPD.cov(:,:,i))) < min_covar
      disp(['resetting singular covariance for node ' num2str(CPD.self)]);
      CPD.cov(:,:,i) = CPD.init_cov(:,:,i);
    end
  end
end