-
Notifications
You must be signed in to change notification settings - Fork 0
/
DIMEc.m~
70 lines (59 loc) · 1.96 KB
/
DIMEc.m~
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
41
42
43
44
45
46
47
48
49
50
51
52
53
54
55
56
57
58
59
60
61
62
63
64
65
66
67
68
69
70
function [Dj_plus, Dj_minus, tau_plus, tau_minus] = DIMEc(pi,mu,Sigma,j,dim, group)
% DIME calculation:
% compute DIME
% on the cluster/suptype level (mixture of normal mixtures)
%
% p: dimension , k: number of clusters
% dim: nnxpp, subset of x-dimension. dim(i,:): ith subset of x. Use 0s to
% keep places
% fj: 1xnn vector
% pi = column k vector probs
% mu = p.k matrix of component means
% Sigma = p.p.k array of variance matrice
% group: groupings of components,row represents component grouping
% j: jth cluster
%Dj_plus = E( f_j |x~\ f_j)/E(f_j | x ~ f_j)
%Dj_minus = E( f_j |x~\ f_j)/E(f_-j | x ~\ f_j)
%tau_plus: upper bound of tau
%tau_minus: lower bound of tau
[p,k] = size(mu);
[nn,pp] = size(dim);
Dj_plus = double(zeros(1,nn));
Dj_minus = Dj_plus;
tau_plus = double(zeros(1,nn));
tau_minus = tau_plus;
gpj = group(j,:);
gpj(gpj==0)=[];
indexj = 1:k; indexj(gpj) = [];
cpj = 1-sum(pi(gpj));
D=zeros(k,k,nn);
for tt = 1:nn
deno = 0; nume = 0; deno1 = 0;
dimm = dim(tt,:); dimm(dimm==0)=[];
for i=1:k
mi=mu(dimm,i); Si=Sigma(dimm,dimm,i); %mi: mean of ith component, Si: variance-covariance matrix for ith component.
for jj=i:k,
D(i,jj,tt)=mvnormpdf(mu(dimm,jj),mi,Si+Sigma(dimm,dimm,jj)); D(jj,i,tt)=D(i,jj,tt); % D(i,j) = f_ij
end
end
for ii = gpj
for ppp = indexj
nume= nume + (pi(ii)/(1-cpj))*(pi(ppp)/cpj)*D(ii,ppp,tt);
end
end
%nume = nume*cpj;
for ii = gpj
for ppp = gpj
deno = deno + pi(ii)/(1-cpj)*(pi(ppp)/(1-cpj))*D(ii,ppp,tt);
end
end
for ii = indexj
for ppp = indexj
deno1 = deno1 + (pi(ii)/cpj)*(pi(ppp)/cpj)*D(ii,ppp,tt);
end
end
Dj_plus(tt) = double(nume/deno); % Delta_j in the paper
Dj_minus(tt) = double(nume/deno1); %Delta_j in the paper
tau_plus(tt) = double((1-cpj)/((1-cpj)+cpj*Dj_plus(tt)));
tau_minus(tt) = double((1-cpj)*Dj_minus(tt)/(cpj+(1-cpj)*Dj_minus(tt)));
end