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spm_PEB.m
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spm_PEB.m
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function [C,P,F] = spm_PEB(y,P,OPT)
% parametric empirical Bayes (PEB) for hierarchical linear models
% FORMAT [C,P,F] = spm_PEB(y,P,OPT)
%
% y - (n x 1) response variable
%
% MODEL SPECIFICATION
%
% P{i}.X - (n x m) ith level design matrix i.e: constraints on <Eb{i - 1}>
% P{i}.C - {q}(n x n) ith level contraints on Cov{e{i}} = Cov{b{i - 1}}
%
% OPT - enforces positively constraints on the covariance hyperparameters
% by adopting a log-normal [flat] hyperprior. default = 0
%
% POSTERIOR OR CONDITIONAL ESTIMATES
%
% C{i}.E - (n x 1) conditional expectation E{b{i - 1}|y}
% C{i}.C - (n x n) conditional covariance Cov{b{i - 1}|y} = Cov{e{i}|y}
% C{i}.M - (n x n) ML estimate of Cov{b{i - 1}} = Cov{e{i}}
% C{i}.h - (q x 1) ith level ReML hyperparameters for covariance:
% Cov{e{i}} = P{i}.h(1)*P{i}.C{1} + ...
%
% LOG EVIDENCE
%
% F - [-ve] free energy F = log evidence = p(y|X,C)
%
% If P{i}.C is not a cell the covariance at that level is assumed to be kown
% and Cov{e{i}} = P{i}.C (i.e. the hyperparameter is fixed at 1)
%
% If P{n}.C is not a cell this is taken to indicate that a full Bayesian
% estimate is required where P{n}.X is the prior expectation and P{n}.C is
% the known prior covariance. For consistency, with PEB, this is implemented
% by setting b{n} = 1 through appropriate constraints at level {n + 1}.
%
% To implement non-hierarchical Bayes with priors on the parameters use
% a two level model setting the second level design matrix to zeros.
%__________________________________________________________________________
%
% Returns the moments of the posterior p.d.f. of the parameters of a
% hierarchical linear observation model under Gaussian assumptions
%
% y = X{1}*b{1} + e{1}
% b{1} = X{2}*b{2} + e{2}
% ...
%
% b{n - 1} = X{n}*b{n} + e{n}
%
% e{n} ~ N{0,Ce{n}}
%
% using Parametic Emprical Bayes (PEB)
%
% Ref: Dempster A.P., Rubin D.B. and Tsutakawa R.K. (1981) Estimation in
% covariance component models. J. Am. Stat. Assoc. 76;341-353
%__________________________________________________________________________
% Copyright (C) 2008 Wellcome Trust Centre for Neuroimaging
% Karl Friston
% $Id: spm_PEB.m 5219 2013-01-29 17:07:07Z spm $
% set default
%--------------------------------------------------------------------------
try
OPT;
catch
OPT = 0;
end
% number of levels (p)
%--------------------------------------------------------------------------
M = 32; % maximum number of iterations
p = length(P);
% check covariance constraints - assume i.i.d. errors conforming to X{i}
%--------------------------------------------------------------------------
for i = 1:p
if ~isfield(P{i},'C')
[n,m] = size(P{i}.X);
if i == 1
P{i}.C = {speye(n,n)};
else
for j = 1:m
k = find(P{i}.X(:,j));
P{i}.C{j} = sparse(k,k,1,n,n);
end
end
end
end
% Construct augmented non-hierarchical model
%==========================================================================
% design matrix and indices
%--------------------------------------------------------------------------
I = {0};
J = {0};
K = {0};
XX = [];
X = 1;
for i = 1:p
% design matrix
%----------------------------------------------------------------------
X = X*P{i}.X;
XX = [XX X];
% indices for ith level parameters
%----------------------------------------------------------------------
[n,m] = size(P{i}.X);
I{i} = (1:n) + I{end}(end);
J{i} = (1:m) + J{end}(end);
end
% augment design matrix and data
%--------------------------------------------------------------------------
n = size(XX,2);
XX = [XX; speye(n,n)];
y = [y; sparse(n,1)];
% last level constraints
%--------------------------------------------------------------------------
n = size(P{p}.X,2);
I{p + 1} = [1:n] + I{end}(end);
q = I{end}(end);
Cb = sparse(q,q);
if ~iscell(P{end}.C)
% Full Bayes: (i.e. Cov(b) = 0, <b> = 1)
%----------------------------------------------------------------------
y( I{end}) = sparse(1:n,1,1);
else
% Empirical Bayes: uniform priors (i.e. Cov(b) = Inf, <b> = 0)
%----------------------------------------------------------------------
Cb(I{end},I{end}) = sparse(1:n,1:n,exp(32));
end
% assemble augmented constraints Q: Cov{e} = Cb + h(i)*Q{i} + ...
%==========================================================================
if ~isfield(P{1},'Q')
% covariance contraints Q on Cov{e{i}} = Cov{b{i - 1}}
%----------------------------------------------------------------------
h = [];
Q = {};
for i = 1:p
% collect constraints on prior covariances - Cov{e{i}}
%------------------------------------------------------------------
if iscell(P{i}.C)
m = length(P{i}.C);
for j = 1:m
[u,v,s] = find(P{i}.C{j});
u = u + I{i}(1) - 1;
v = v + I{i}(1) - 1;
Q{end + 1} = sparse(u,v,s,q,q);
end
% indices for ith-level hyperparameters
%--------------------------------------------------------------
try
K{i} = [1:m] + K{end}(end);
catch
K{i} = [1:m];
end
else
% unless they are known - augment Cb
%--------------------------------------------------------------
[u,v,s] = find(P{i}.C + speye(length(P{i}.C))*1e-6);
u = u + I{i}(1) - 1;
v = v + I{i}(1) - 1;
Cb = Cb + sparse(u,v,s,q,q);
% indices for ith-level hyperparameters
%--------------------------------------------------------------
K{i} = [];
end
end
% note overlapping bases - requiring 2nd order M-Step derivatives
%----------------------------------------------------------------------
m = length(Q);
d = sparse(m,m);
for i = 1:m
XQX{i} = XX'*Q{i}*XX;
end
for i = 1:m
for j = i:m
o = nnz(XQX{i}*XQX{j});
d(i,j) = o;
d(j,i) = o;
end
end
% log-transform and save
%----------------------------------------------------------------------
h = zeros(m,1);
if OPT
hP = speye(m,m)/16;
else
hP = speye(m,m)/exp(16);
for i = 1:m
h(i) = any(diag(Q{i}));
end
end
P{1}.hP = hP;
P{1}.Cb = Cb;
P{1}.Q = Q;
P{1}.h = h;
P{1}.K = K;
P{1}.d = d;
end
hP = P{1}.hP;
Cb = P{1}.Cb;
Q = P{1}.Q;
h = P{1}.h;
K = P{1}.K;
d = P{1}.d;
% Iterative EM
%--------------------------------------------------------------------------
m = length(Q);
dFdh = zeros(m,1);
dFdhh = zeros(m,m);
for k = 1:M
% inv(Cov(e)) - iC(h)
%----------------------------------------------------------------------
Ce = Cb;
for i = 1:m
if OPT
Ce = Ce + Q{i}*exp(h(i));
else
Ce = Ce + Q{i}*h(i);
end
end
iC = spm_inv(Ce,exp(-16));
% E-step: conditional mean E{B|y} and covariance cov(B|y)
%======================================================================
iCX = iC*XX;
Cby = spm_inv(XX'*iCX);
B = Cby*(iCX'*y);
% M-step: ReML estimate of hyperparameters (if m > 0)
%======================================================================
if m == 0, break, end
% Gradient dF/dh (first derivatives)
%----------------------------------------------------------------------
Py = iC*(y - XX*B);
iCXC = iCX*Cby;
for i = 1:m
% dF/dh = -trace(dF/diC*iC*Q{i}*iC)
%------------------------------------------------------------------
PQ{i} = iC*Q{i} - iCXC*(iCX'*Q{i});
if OPT
PQ{i} = PQ{i}*exp(h(i));
end
dFdh(i) = -trace(PQ{i})/2 + y'*PQ{i}*Py/2;
end
% Expected curvature E{ddF/dhh} (second derivatives)
%----------------------------------------------------------------------
for i = 1:m
for j = i:m
if d(i,j)
% ddF/dhh = -trace{P*Q{i}*P*Q{j}}
%----------------------------------------------------------
dFdhh(i,j) = -spm_trace(PQ{i},PQ{j})/2;
dFdhh(j,i) = dFdhh(i,j);
end
end
end
% add hyperpriors
%----------------------------------------------------------------------
dFdhh = dFdhh - hP;
% Fisher scoring: update dh = -inv(ddF/dhh)*dF/dh
%----------------------------------------------------------------------
dh = -pinv(dFdhh)*dFdh;
h = h + dh;
% Convergence
%======================================================================
w = norm(dh,1);
% fprintf('%-30s: %i %30s%e\n',' PEB Iteration',k,'...',full(w));
% if dF < 0.01
%----------------------------------------------------------------------
if dFdh'*dh < 1e-2, break, end
% if dh^2 < 1e-8
%----------------------------------------------------------------------
if w < 1e-4, break, end
% if log-normal hyperpriors and h < exp(-16)
%----------------------------------------------------------------------
if OPT && h < -16, break, end
end
% place hyperparameters in P{1} and output structure for {n + 1}
%--------------------------------------------------------------------------
P{1}.h = h + exp(-32);
C{p + 1}.E = B(J{p});
C{p + 1}.M = Cb(I{end},I{end});
% recursive computation of conditional means E{b|y}
%--------------------------------------------------------------------------
for i = p:-1:2
C{i}.E = B(J{i - 1}) + P{i}.X*C{i + 1}.E;
end
% hyperpriors - precision
%--------------------------------------------------------------------------
if OPT
h = exp(h);
end
% conditional covariances Cov{b|y} and ReML esimtates of Ce{i) = Cb{i - 1}
%--------------------------------------------------------------------------
for i = 1:p
C{i + 1}.C = Cby(J{i},J{i});
C{i}.M = Ce(I{i},I{i});
C{i}.h = h(K{i});
end
% log evidence = ln p(y|X,C) = F = [-ve] free energy
%--------------------------------------------------------------------------
if nargout > 2
% condotional covariance of h
%----------------------------------------------------------------------
Ph = -dFdhh;
% log evidence = F
%----------------------------------------------------------------------
F = - Py'*Ce*Py/2 ...
- length(I{1})*log(2*pi)/2 ...
- spm_logdet(Ce)/2 ...
- spm_logdet(Ph)/2 ...
+ spm_logdet(hP)/2 ...
+ spm_logdet(Cby)/2;
end
% warning
%--------------------------------------------------------------------------
if k == M, warning('maximum number of iterations exceeded'), end