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function [color,centroids]=som_kmeanscolor2(mode,sM,C,initRGB,contrast,R)
% SOM_KMEANSCOLOR2 Color codes a SOM according to averaged or best K-means clustering
%
% color = som_kmeanscolor2('average',sM, C, [initRGB], [contrast],[R])
%
% color=som_kmeanscolor2('average',sM,[2 4 8 16],som_colorcode(sM,'rgb1'),'enhanced');
% [color,centroid]=som_kmeanscolor2('best',sM,15,[],'flat',R);
%
% Input and output arguments ([]'s are optional):
%
% mode (string) 'average' or 'best', defalut: 'average'
% sM (struct) a map struct
% C (vector) number of clusters
% [initRGB] (string, matrix) a color code string accepted by SOM_COLORCODE
% or an Mx3 matrix of RGB triples, where M is the number
% of map units. Default: SOM_COLORCODEs default
% [contrast] (string) 'flat', 'enhanced' color contrast mode, default:
% 'enhanced'.
% [R] (scalar) number of K-means trials, default: 30.
% color (matrix) Mx3xC of RGB triples
% centroid (array of matrices) centroid{i} includes codebook for the best
% k-means for C(i) clusters, i.e. the cluster centroids corresponding to
% the color code color(:,:,i).
%
% The function gives a set of color codes for the SOM according to K-means
% clustering. It has two operation modes:
%
% 'average': The idea of coloring is that the color of the units belonging to the same
% cluster is the mean of the original RGB values (see SOM_COLORCODE) of the map units
% belonging to the cluster (see SOM_CLUSTERCOLOR). The K-means clustering is made,
% by default, 30 times and the resulting color codes are averaged for
% each specified number of clusters C(i), i=1,...,k. In a way, the resulting averaged color
% codes reflect the stability of the K-means clustering made on the map units.
%
% 'best': runs the k-means R times for C(i), i=1,...,n clusters as in previous mode,
% but instead of averaging all the R color codes, it picks the one that corresponds to the
% best k-means clustering for each C(i). The 'best' is the one with the lowest
% quantization error. The result may differ from run to run.
%
% EXAMPLE
%
% load iris; % or any other map struct sM
% color=som_kmeanscolor2('average',sM,[2:6]);
% som_show(sM,'umat','all','color',color);
%
% See also SOM_KMEANS, SOM_SHOW, SOM_COLORCODE, SOM_CLUSTERCOLOR, SOM_KMEANSCOLOR
% Contributed to SOM Toolbox 2.0, 2001 February by Johan Himberg
% Copyright (c) by Johan Himberg
% http://www.cis.hut.fi/projects/somtoolbox/
%%% Check number of inputs
error(nargchk(3, 6, nargin)); % check no. of input args
%%% Check input args & set defaults
if ~vis_valuetype(mode,{'string'}),
error('Mode must be a string.');
end
switch lower(mode),
case{'average','best'}
;
otherwise
error('Mode must be string ''average'' or ''best''.');
end
if isstruct(sM) & isfield(sM,'type') & strcmp(sM.type,'som_map'),
[tmp,lattice,msize]=vis_planeGetArgs(sM);
munits=prod(msize);
if length(msize)>2
error('Does not work with 3D maps.')
end
else
error('Map struct required for the second input argument!');
end
if ~vis_valuetype(C,{'1xn','nx1'}),
error('Vector value expected for cluster number.');
end
% Round C and check
C=round(C(:)');
if any(C<2),
error('Cluster number must be 2 or more.');
end
% check initial color coding
if nargin<4 | isempty(initRGB)
initRGB=som_colorcode(sM);
end
% check contrast checking
if nargin<5 | isempty(contrast),
contrast='enhanced';
end
if ~ischar(contrast),
error('String input expected for input arg. ''contrast''.');
else
switch lower(contrast)
case {'flat','enhanced'}
;
otherwise
error(['''flat'' or ''enhanced'' expected for '...
'input argument ''contrast''.']);
end
end
if ischar(initRGB),
try
initRGB=som_colorcode(sM,initRGB);
catch
error(['Color code ' initRGB ...
'was not recognized by SOM_COLORCODE.']);
end
elseif vis_valuetype(initRGB,{'nx3rgb',[munits 3]},'all'),
;
else
error(['The initial color code must be a string '...
'or an Mx3 matrix of RGB triples.']);
end
if nargin<6|isempty(R),
R=30;
end
if ~vis_valuetype(R,{'1x1'}),
error('''R'' must be scalar.');
end
%%% Action %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
disp('Wait...');
index=0; hit_=zeros(munits,munits);
switch mode,
%% Averaged k-means coloring
case 'average'
for k=C,
disp(['Running K-means for ' num2str(k) ' clusters...']);
color_=zeros(munits,3);
colord_=color_;
% Average R k-means colorings for C clusters
for j=1:R,
[dummy,c]=som_kmeans('batch',sM,k,100,0); % max 100 iterations, verbose off
color_=color_+som_clustercolor(sM,c,initRGB);
end
index=index+1;
color(:,:,index)=color_./R;
end
%% coloring for 'best' k-means coloring
case 'best'
for k=C,
disp(['Running K-means for ' num2str(k) ' clusters...']);
c=[];err=Inf; div=[];
%% look for the best k-means among R trials
for i=1:R,
[c_,div_,err_(i)]=som_kmeans('batch',sM,k,100,0); % max 100 iterations, verbose off
if err_(i)<err,
err=err_(i); c=c_; div=div_;
end
end
% record the 'best' k-means for C clusters
index=index+1;
color(:,:,index)=som_clustercolor(sM,div,initRGB);
centroid{index}=c;
end
end
%%% Build output
switch contrast
case 'flat'
;
case 'enhanced'
warning off;
ncolor=maxnorm(color);
ncolor(~isfinite(ncolor))=color(~isfinite(ncolor));
color=ncolor;
warning on;
end
%%% Subfunctions %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
function X=maxnorm(x)
% normalize columns of x between [0,1]
x=x-repmat(min(x),[size(x,1) 1 1]);
X=x./repmat(max(x),[size(x,1) 1 1]);