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function [P] = cca(D, P, epochs, Mdist, alpha0, lambda0)
%CCA Projects data vectors using Curvilinear Component Analysis.
%
% P = cca(D, P, epochs, [Dist], [alpha0], [lambda0])
%
% P = cca(D,2,10); % projects the given data to a plane
% P = cca(D,pcaproj(D,2),5); % same, but with PCA initialization
% P = cca(D, 2, 10, Dist); % same, but the given distance matrix is used
%
% Input and output arguments ([]'s are optional):
% D (matrix) the data matrix, size dlen x dim
% (struct) data or map struct
% P (scalar) output dimension
% (matrix) size dlen x odim, the initial projection
% epochs (scalar) training length
% [Dist] (matrix) pairwise distance matrix, size dlen x dlen.
% If the distances in the input space should
% be calculated otherwise than as euclidian
% distances, the distance from each vector
% to each other vector can be given here,
% size dlen x dlen. For example PDIST
% function can be used to calculate the
% distances: Dist = squareform(pdist(D,'mahal'));
% [alpha0] (scalar) initial step size, 0.5 by default
% [lambda0] (scalar) initial radius of influence, 3*max(std(D)) by default
%
% P (matrix) size dlen x odim, the projections
%
% Unknown values (NaN's) in the data: projections of vectors with
% unknown components tend to drift towards the center of the
% projection distribution. Projections of totally unknown vectors are
% set to unknown (NaN).
%
% See also SAMMON, PCAPROJ.
% Reference: Demartines, P., Herault, J., "Curvilinear Component
% Analysis: a Self-Organizing Neural Network for Nonlinear
% Mapping of Data Sets", IEEE Transactions on Neural Networks,
% vol 8, no 1, 1997, pp. 148-154.
% Contributed to SOM Toolbox 2.0, February 2nd, 2000 by Juha Vesanto
% Copyright (c) by Juha Vesanto
% http://www.cis.hut.fi/projects/somtoolbox/
% juuso 171297 040100
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
%% Check arguments
error(nargchk(3, 6, nargin)); % check the number of input arguments
% input data
if isstruct(D),
if strcmp(D.type,'som_map'), D = D.codebook; else D = D.data; end
end
[noc dim] = size(D);
noc_x_1 = ones(noc, 1); % used frequently
me = zeros(1,dim); st = zeros(1,dim);
for i=1:dim,
me(i) = mean(D(find(isfinite(D(:,i))),i));
st(i) = std(D(find(isfinite(D(:,i))),i));
end
% initial projection
if prod(size(P))==1,
P = (2*rand(noc,P)-1).*st(noc_x_1,1:P) + me(noc_x_1,1:P);
else
% replace unknown projections with known values
inds = find(isnan(P)); P(inds) = rand(size(inds));
end
[dummy odim] = size(P);
odim_x_1 = ones(odim, 1); % this is used frequently
% training length
train_len = epochs*noc;
% random sample order
rand('state',sum(100*clock));
sample_inds = ceil(noc*rand(train_len,1));
% mutual distances
if nargin<4 | isempty(Mdist) | all(isnan(Mdist(:))),
fprintf(2, 'computing mutual distances\r');
dim_x_1 = ones(dim,1);
for i = 1:noc,
x = D(i,:);
Diff = D - x(noc_x_1,:);
N = isnan(Diff);
Diff(find(N)) = 0;
Mdist(:,i) = sqrt((Diff.^2)*dim_x_1);
N = find(sum(N')==dim); %mutual distance unknown
if ~isempty(N), Mdist(N,i) = NaN; end
end
else
% if the distance matrix is output from PDIST function
if size(Mdist,1)==1, Mdist = squareform(Mdist); end
if size(Mdist,1)~=noc,
error('Mutual distance matrix size and data set size do not match');
end
end
% alpha and lambda
if nargin<5 | isempty(alpha0) | isnan(alpha0), alpha0 = 0.5; end
alpha = potency_curve(alpha0,alpha0/100,train_len);
if nargin<6 | isempty(lambda0) | isnan(lambda0), lambda0 = max(st)*3; end
lambda = potency_curve(lambda0,0.01,train_len);
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
%% Action
k=0; fprintf(2, 'iterating: %d / %d epochs\r',k,epochs);
for i=1:train_len,
ind = sample_inds(i); % sample index
dx = Mdist(:,ind); % mutual distances in input space
known = find(~isnan(dx)); % known distances
if ~isempty(known),
% sample vector's projection
y = P(ind,:);
% distances in output space
Dy = P(known,:) - y(noc_x_1(known),:);
dy = sqrt((Dy.^2)*odim_x_1);
% relative effect
dy(find(dy==0)) = 1; % to get rid of div-by-zero's
fy = exp(-dy/lambda(i)) .* (dx(known) ./ dy - 1);
% Note that the function F here is e^(-dy/lambda))
% instead of the bubble function 1(lambda-dy) used in the
% paper.
% Note that here a simplification has been made: the derivatives of the
% F function have been ignored in calculating the gradient of error
% function w.r.t. to changes in dy.
% update
P(known,:) = P(known,:) + alpha(i)*fy(:,odim_x_1).*Dy;
end
% track
if rem(i,noc)==0,
k=k+1; fprintf(2, 'iterating: %d / %d epochs\r',k,epochs);
end
end
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
%% clear up
% calculate error
error = cca_error(P,Mdist,lambda(train_len));
fprintf(2,'%d iterations, error %f \n', epochs, error);
% set projections of totally unknown vectors as unknown
unknown = find(sum(isnan(D)')==dim);
P(unknown,:) = NaN;
return;
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
%% tips
% to plot the results, use the code below
%subplot(2,1,1),
%switch(odim),
% case 1, plot(P(:,1),ones(dlen,1),'x')
% case 2, plot(P(:,1),P(:,2),'x');
% otherwise, plot3(P(:,1),P(:,2),P(:,3),'x'); rotate3d on
%end
%subplot(2,1,2), dydxplot(P,Mdist);
% to a project a new point x in the input space to the output space
% do the following:
% Diff = D - x(noc_x_1,:); Diff(find(isnan(Diff))) = 0;
% dx = sqrt((Diff.^2)*dim_x_1);
% p = project_point(P,x,dx); % this function can be found from below
% tlen = size(p,1);
% plot(P(:,1),P(:,2),'bx',p(tlen,1),p(tlen,2),'ro',p(:,1),p(:,2),'r-')
% similar trick can be made to the other direction
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
%% subfunctions
function vals = potency_curve(v0,vn,l)
% curve that decreases from v0 to vn with a rate that is
% somewhere between linear and 1/t
vals = v0 * (vn/v0).^([0:(l-1)]/(l-1));
function error = cca_error(P,Mdist,lambda)
[noc odim] = size(P);
noc_x_1 = ones(noc,1);
odim_x_1 = ones(odim,1);
error = 0;
for i=1:noc,
known = find(~isnan(Mdist(:,i)));
if ~isempty(known),
y = P(i,:);
Dy = P(known,:) - y(noc_x_1(known),:);
dy = sqrt((Dy.^2)*odim_x_1);
fy = exp(-dy/lambda);
error = error + sum(((Mdist(known,i) - dy).^2).*fy);
end
end
error = error/2;
function [] = dydxplot(P,Mdist)
[noc odim] = size(P);
noc_x_1 = ones(noc,1);
odim_x_1 = ones(odim,1);
Pdist = zeros(noc,noc);
for i=1:noc,
y = P(i,:);
Dy = P - y(noc_x_1,:);
Pdist(:,i) = sqrt((Dy.^2)*odim_x_1);
end
Pdist = tril(Pdist,-1);
inds = find(Pdist > 0);
n = length(inds);
plot(Pdist(inds),Mdist(inds),'.');
xlabel('dy'), ylabel('dx')
function p = project_point(P,x,dx)
[noc odim] = size(P);
noc_x_1 = ones(noc,1);
odim_x_1 = ones(odim,1);
% initial projection
[dummy,i] = min(dx);
y = P(i,:)+rand(1,odim)*norm(P(i,:))/20;
% lambda
lambda = norm(std(P));
% termination
eps = 1e-3; i_max = noc*10;
i=1; p(i,:) = y;
ready = 0;
while ~ready,
% mutual distances
Dy = P - y(noc_x_1,:); % differences in output space
dy = sqrt((Dy.^2)*odim_x_1); % distances in output space
f = exp(-dy/lambda);
fprintf(2,'iteration %d, error %g \r',i,sum(((dx - dy).^2).*f));
% all the other vectors push the projected one
fy = f .* (dx ./ dy - 1) / sum(f);
% update
step = - sum(fy(:,odim_x_1).*Dy);
y = y + step;
i=i+1;
p(i,:) = y;
ready = (norm(step)/norm(y) < eps | i > i_max);
end
fprintf(2,'\n');