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Iccs_mvn_Pind.m
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Iccs_mvn_Pind.m
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function Iccs = Iccs_mvn(A, Cfull, varsizes)
% calculate redundancy between a set of Gaussian sources
% from pointwise common change in surprise
% using conditional independent joint-source distributions
%
% A is cell array of sources
% Cfull is full covariance of system
% varsizes specifies the number of variables in each X_i and S (S last)
if sum(varsizes) ~= size(Cfull,1)
error('wrong number of variables specified')
end
if length(varsizes)~=3
error('only 2 variables supported')
end
NA = length(A);
NVs = varsizes(end);
Nx = length(varsizes-1);
NVx = varsizes(1:end-1);
varstart = cumsum(varsizes)+1;
varstart = [1 varstart(1:end-1)];
uniquevars = unique([A{:}]);
sidx = varstart(end):(varstart(end)+NVs-1);
Cs = Cfull(sidx,sidx);
% build Cax for each source
AC = [];
for ai=1:NA
thsA = A{ai};
aidxfull = {};
aidx = {};
thsvstart = 1;
for vi=1:length(thsA)
aidxfull{vi} = varstart(thsA(vi)):(varstart(thsA(vi))+NVx(thsA(vi))-1);
thsL = length(aidxfull{vi});
aidx{vi} = thsvstart:(thsvstart+thsL-1);
thsvstart = thsvstart+thsL;
end
thsNv = length(cell2mat(aidx));
Cas = zeros(thsNv+NVs);
Ca = zeros(thsNv);
% fill in blocks
% diagonal
for vi=1:length(thsA)
Ca(aidx{vi},aidx{vi}) = Cfull(aidxfull{vi},aidxfull{vi});
end
% off diagonal
for vi=1:length(thsA)
for vj=1:length(thsA)
if vi==vj
continue
end
Ca(aidx{vi},aidx{vj}) = Cfull(aidxfull{vi},aidxfull{vj});
end
end
Cas(1:thsNv,1:thsNv) = Ca;
% joint with S
% diagonal
thssidx = thsNv+1:thsNv+NVs;
Cas(thssidx,thssidx) = Cs;
% off diagonal
for vi=1:length(thsA)
Cas(aidx{vi},thssidx) = Cfull(aidxfull{vi},sidx);
Cas(thssidx,aidx{vi}) = Cfull(sidx,aidxfull{vi});
end
Casoff = Cas(1:thsNv,thssidx);
CXYY1 = Casoff * pinv(Cs);
Cacs = Ca - CXYY1*Cas(thssidx,1:thsNv);
MacsF = CXYY1;
AC(ai).Ca = Ca;
AC(ai).Cas = Cas;
AC(ai).Cacs = Cacs;
AC(ai).Casoff = Casoff;
AC(ai).MacsF = CXYY1;
AC(ai).Nv = thsNv;
end
if NA==1
% use closed form expression
chA = chol(AC(1).Ca);
chS = chol(Cs);
chAS = chol(AC(1).Cas);
% normalisations cancel for information
HA = sum(log(diag(chA))); % + 0.5*Nvarx*log(2*pi*exp(1));
HS = sum(log(diag(chS))); % + 0.5*Nvary*log(2*pi*exp(1));
HAS = sum(log(diag(chAS))); % + 0.5*(Nvarx+Nvary)*log(2*pi*exp(1));
Iccs = (HA + HS - HAS) / log(2);
end
if NA==2
% Covariance for Pind(A1,A2)
thsNv = AC(1).Nv + AC(2).Nv + NVs;
ANv = AC(1).Nv + AC(2).Nv;
a1idx = 1:AC(1).Nv;
a2idx = AC(1).Nv+1:AC(1).Nv+AC(2).Nv;
% start from conditional Pind
Cind = zeros(ANv,ANv);
Cind(a1idx,a1idx) = AC(1).Cacs;
Cind(a2idx,a2idx) = AC(2).Cacs;
% add shur term
Caas = cat(1, AC(1).Casoff, AC(2).Casoff);
Cind = Cind + Caas*pinv(Cs)*Caas.';
% full Pind
Cfullind = zeros(thsNv,thsNv);
Cfullind(1:ANv,1:ANv) = Cind;
thssidx = AC(1).Nv+AC(2).Nv+1:AC(1).Nv+AC(2).Nv+NVs;
Cfullind(thssidx,thssidx) = Cs;
% off diagonal blocks including S
Cfullind(a1idx,thssidx) = AC(1).Casoff;
Cfullind(thssidx,a1idx) = AC(1).Casoff.';
Cfullind(a2idx,thssidx) = AC(2).Casoff;
Cfullind(thssidx,a2idx) = AC(2).Casoff.';
% Monte Carlo Integration for Iccs
% 100,000 works well for 5d space.
% 10,000 might be ok but some variance
Nmc = 100000;
% integrate over full space
intD = AC(1).Nv + AC(2).Nv + NVs;
mcx = mvnrnd(zeros(1,ANv+NVs), Cfullind, Nmc);
px = logmvnpdf(mcx(:,a1idx),zeros(1,AC(1).Nv),AC(1).Ca);
pxcs = logmvnpdf(mcx(:,a1idx), (AC(1).MacsF*mcx(:,thssidx)')', AC(1).Cacs);
py = logmvnpdf(mcx(:,a2idx),zeros(1,AC(2).Nv),AC(2).Ca);
pycs = logmvnpdf(mcx(:,a2idx), (AC(2).MacsF*mcx(:,thssidx)')', AC(2).Cacs);
a12idx = 1:AC(1).Nv + AC(2).Nv;
pxy = logmvnpdf(mcx(:,a12idx), zeros(1,ANv), Cind);
pxycs = pxcs + pycs;
dhx = pxcs - px;
dhy = pycs - py;
dhxy = pxycs - pxy;
lnii = dhx + dhy - dhxy;
keep = sign(dhx) == sign(lnii) & sign(dhx) == sign(dhy) & sign(dhx) == sign(dhxy);
lnii(~keep) = 0;
Iccs = nanmean(lnii);
% convert to bits
Iccs = Iccs ./ log(2);
end