www.gusucode.com > SOM算法,matlab程序,是经典的教科书的例子程序 > somtoolbox/som_distortion.m
function [adm,admu,tdmu] = som_distortion(sM, D, arg1, arg2)
%SOM_DISTORTION Calculate distortion measure for the map.
%
% [adm,admu,tdmu] = som_distortion(sMap, D, [radius], ['prob'])
%
% adm = som_distortion(sMap,D);
% [adm,admu] = som_distortion(sMap,D);
% som_show(sMap,'color',admu);
%
% Input and output arguments:
% sMap (struct) a map struct
% D (struct) a data struct
% (matrix) size dlen x dim, a data matrix
% [radius] (scalar) neighborhood function radius to be used.
% Defaults to the last radius_fin in the
% trainhist field of the map struct, or 1 if
% that is missing.
% ['prob'] (string) If given, this argument forces the
% neigborhood function values for each map
% unit to be normalized so that they sum to 1.
%
% adm (scalar) average distortion measure (sum(dm)/dlen)
% admu (vector) size munits x 1, average distortion in each unit
% tdmu (vector) size munits x 1, total distortion for each unit
%
% The distortion measure is defined as:
% 2
% E = sum sum h(bmu(i),j) ||m(j) - x(i)||
% i j
%
% where m(i) is the ith prototype vector of SOM, x(j) is the jth data
% vector, and h(.,.) is the neighborhood function. In case of fixed
% neighborhood and discreet data, the distortion measure can be
% interpreted as the energy function of the SOM. Note, though, that
% the learning rule that follows from the distortion measure is
% different from the SOM training rule, so SOM only minimizes the
% distortion measure approximately.
%
% If the 'prob' argument is given, the distortion measure can be
% interpreted as an expected quantization error when the neighborhood
% function values give the likelyhoods of accidentally assigning
% vector j to unit i. The normal quantization error is a special case
% of this with zero incorrect assignement likelihood.
%
% NOTE: when calculating BMUs and distances, the mask of the given
% map is used.
%
% See also SOM_QUALITY, SOM_BMUS, SOM_HITS.
% Reference: Kohonen, T., "Self-Organizing Map", 2nd ed.,
% Springer-Verlag, Berlin, 1995, pp. 120-121.
%
% Graepel, T., Burger, M. and Obermayer, K.,
% "Phase Transitions in Stochastic Self-Organizing Maps",
% Physical Review E, Vol 56, No 4, pp. 3876-3890 (1997).
% Contributed to SOM Toolbox vs2, Feb 3rd, 2000 by Juha Vesanto
% Copyright (c) by Juha Vesanto
% http://www.cis.hut.fi/projects/somtoolbox/
% Version 2.0beta juuso 030200
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
%% check arguments
% input arguments
if nargin < 2, error('Not enough input arguments.'); end
% map
M = sM.codebook;
munits = prod(sM.topol.msize);
% data
if isstruct(D), D = D.data; end
[dlen dim] = size(D);
% arg1, arg2
rad = NaN;
normalize = 0;
if nargin>2,
if isnumeric(arg1), rad = arg1;
elseif ischar(arg1) & strcmp(arg1,'prob'), normalize = 0;
end
end
if nargin>3,
if isnumeric(arg2), rad = arg2;
elseif ischar(arg2) & strcmp(arg2,'prob'), normalize = 0;
end
end
% neighborhood radius
if isempty(rad) | isnan(rad),
if ~isempty(sM.trainhist), rad = sM.trainhist(end).radius_fin;
else rad = 1;
end
end
if rad<eps, rad = eps; end
% neighborhood
Ud = som_unit_dists(sM.topol);
switch sM.neigh,
case 'bubble', H = (Ud <= rad);
case 'gaussian', H = exp(-(Ud.^2)/(2*rad*rad));
case 'cutgauss', H = exp(-(Ud.^2)/(2*rad*rad)) .* (Ud <= rad);
case 'ep', H = (1 - (Ud.^2)/rad) .* (Ud <= rad);
end
if normalize,
for i=1:munits, H(:,i) = H(:,i)/sum(H(:,i)); end
end
% total distortion measure
mu_x_1 = ones(munits,1);
tdmu = zeros(munits,1);
hits = zeros(munits,1);
for i=1:dlen,
x = D(i,:); % data sample
known = ~isnan(x); % its known components
Dx = M(:,known) - x(mu_x_1,known); % each map unit minus the vector
dist2 = (Dx.^2)*sM.mask(known); % squared distances
[qerr bmu] = min(dist2); % find BMU
tdmu = tdmu + dist2.*H(:,bmu); % add to distortion measure
hits(bmu) = hits(bmu)+1; % add to hits
end
% average distortion per unit
admu = tdmu;
ind = find(hits>0);
admu(ind) = admu(ind) ./ hits(ind);
% average distortion measure
adm = sum(tdmu)/dlen;
return;
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%