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cvhmmmar.m
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cvhmmmar.m
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function [mcv,cv,rmcv_rand,rcv_rand,rmcv_train,rcv_train] = cvhmmmar(data,T,options)
%
% Obtains the cross-validated sum of prediction quadratic errors.
%
% INPUT
% data observations, either a struct with X (time series) and C (classes, optional)
% or just a matrix containing the time series
% T length of series
% options structure with the training options - see documentation.
% Must contain a field cvfolds, with the number of CV folds,
% or with a CV folds structure as returned by cvpartition
%
% OUTPUT
% mcv the averaged cross-validated likelihood and/or fractional mean squared error
% cv the averaged cross-validated likelihood and/or fractional mean squared error per fold
% rmcv_rand the mean ratio of mcv for the found solution by the mcv for a random solution
% log(test / random)
% rcv_rand the ratio of mcv for the found solution by the mcv for a random solution
% log(test / random)
% mtr the average training likelihood and/or fractional mean squared error
% rmcv_train the mean ratio of train / test, which can considered an index of overfitting
% log(train / test)
% rcv_train the ratio of train / test, which can considered an index of overfitting
% log(train / test)
%
% Author: Diego Vidaurre, OHBA, University of Oxford
if iscell(T)
if size(T,1)==1, T = T'; end
for i = 1:length(T)
if size(T{i},1)==1, T{i} = T{i}'; end
end
end
N = length(T);
if isstruct(data) && isfield(data,'C')
warning('C will not be used here')
end
get_ratio_rand = nargout > 2;
get_ratio_train = nargout > 4;
% is this going to be using the stochastic learning scheme?
stochastic_learn = isfield(options,'BIGNbatch') && (options.BIGNbatch < N && options.BIGNbatch > 0);
if stochastic_learn
error('Stochastic learning cannot currently be used within CV')
end
options = checkspelling(options);
if xor(iscell(data),iscell(T)), error('X and T must be cells, either both or none of them.'); end
if iscell(T)
T = cell2mat(T);
end
checkdatacell;
[options,data] = checkoptions(options,data,T,1);
if options.cvmode~=1
error('The use of options.cvmode different from 1 has been discontinued.')
end
if ~all(options.grouping==1)
error('grouping option is not yet implemented in cvhmmmar')
end
options.verbose = options.cvverbose;
options.dropstates = 0;
options.updateGamma = options.K>1;
options.updateP = options.updateGamma;
if ~isobject(options.cvfolds)
%options.cvfolds = crossvalind('Kfold', length(T), options.cvfolds);
options.cvfolds = cvpartition(length(T),'KFold',options.cvfolds);
end
nfolds = options.cvfolds.NumTestSets;
%orders = formorders(options.order,options.orderoffset,options.timelag,options.exptimelag);
%Sind = formindexes(orders,options.S) == 1;
%if ~options.zeromean, Sind = [true(1,size(Sind,2)); Sind]; end
maxorder = options.maxorder;
cv = zeros(nfolds,1);
rcv_rand = zeros(nfolds,1);
rcv_train = zeros(nfolds,1);
%%% Preprocessing
% Standardise data and control for ackward trials
data = standardisedata(data,T,options.standardise);
% Filtering
if ~isempty(options.filter)
data = filterdata(data,T,options.Fs,options.filter); options.filter = [];
end
% Detrend data
if options.detrend
data = detrenddata(data,T); options.detrend = 0;
end
% Leakage correction
if options.leakagecorr ~= 0
data = leakcorr(data,T,options.leakagecorr); options.leakagecorr = 0;
end
% Hilbert envelope
if options.onpower
data = rawsignal2power(data,T); options.onpower = 0;
end
% Leading Phase Eigenvectors
if options.leida
data = leadingPhEigenvector(data,T); options.leida = 0;
end
% pre-embedded PCA transform
if length(options.pca_spatial) > 1 || (options.pca_spatial > 0 && options.pca_spatial ~= 1)
if isfield(options,'As')
data.X = bsxfun(@minus,data.X,mean(data.X));
data.X = data.X * options.As;
else
[options.As,data.X] = highdim_pca(data.X,T,options.pca_spatial);
options.pca_spatial = size(options.As,2);
end
options.pca_spatial = [];
end
% Embedding
if length(options.embeddedlags) > 1
[data,T] = embeddata(data,T,options.embeddedlags); options.embeddedlags = 0;
end
% PCA transform
if length(options.pca) > 1 || (options.pca > 0 && options.pca ~= 1)
if isfield(options,'A')
data.X = bsxfun(@minus,data.X,mean(data.X));
data.X = data.X * options.A;
else
options.A = highdim_pca(data.X,T,options.pca,0,0,0,options.varimax);
end
else
options.ndim = size(data.X,2);
end
% Downsampling
if options.downsample > 0
[data,T] = downsampledata(data,T,options.downsample,options.Fs);
options.downsample = 0;
end
if options.pcamar > 0 && ~isfield(options,'B')
% PCA on the predictors of the MAR regression, per lag: X_t = \sum_i X_t-i * B_i * W_i + e
options.B = pcamar_decomp(data,T,options);
options.pcamar = 0;
end
if options.pcapred > 0 && ~isfield(options,'V')
% PCA on the predictors of the MAR regression, together:
% Y = X * V * W + e, where X contains all the lagged predictors
% So, unlike B, V draws from the temporal dimension and not only spatial
options.V = pcapred_decomp(data,T,options);
options.pcapre = 0;
end
for fold = 1:nfolds
indtr = []; Ttr = [];
indte = []; Tte = [];
test = [];
cvtest = options.cvfolds.test(fold);
% build fold
for i = 1:length(T)
t0 = sum(T(1:(i-1)))+1; t1 = sum(T(1:i));
Ti = t1-t0+1;
if cvtest(i) % in testing
indte = [indte (t0:t1)];
Tte = [Tte Ti];
test = [test; ones(Ti,1)];
else % in training
indtr = [indtr (t0:t1)];
Ttr = [Ttr Ti];
end
end
datatr.X = data.X(indtr,:);
datate.X = data.X(indte,:);
%datatr.C = data.C(indtr,:);
%datate.C = data.C(indte,:);
if get_ratio_rand
options_r = options;
options_r.cyc = 1;
options_r.inittype = 'random';
options_r.updateGamma = 0;
if isfield(options_r,'orders')
options_r = rmfield(options_r,'orders');
end
if isfield(options_r,'maxorder')
options_r = rmfield(options_r,'maxorder');
end
hmmtr_r = hmmmar (datatr,Ttr,options_r);
[~,~,~,LL_r] = hsinference(datate,Tte,hmmtr_r,[],[],[],[],[],true);
LL_r = sum(log(LL_r)) / size(datate.X,1); % get average
end
if options.verbose, fprintf('CV fold %d, repetition %d \n',fold); end
if isfield(options,'orders')
options = rmfield(options,'orders');
end
if isfield(options,'maxorder')
options = rmfield(options,'maxorder');
end
hmmtr = hmmmar (datatr,Ttr,options);
%hmmtr.train.Sind = Sind;
hmmtr.train.maxorder = maxorder;
% test
[~,~,~,LL] = hsinference(datate,Tte,hmmtr,[],[],[],[],[],true);
cv(fold) = sum(log(LL)) / size(datate.X,1); % get average
if get_ratio_rand
rcv_rand(fold) = cv(fold) - LL_r; % log(test / random)
end
% train
if get_ratio_train
[~,~,~,LL] = hsinference(datatr,Ttr,hmmtr,[],[],[],[],[],true);
LL = sum(log(LL)) / size(datatr.X,1); % get average
rcv_train(fold) = LL - cv(fold); % log(train / test)
%if rcv_train(fold)<0, keyboard; end
end
end
mcv = mean(cv); % mean average LL
rmcv_rand = mean(rcv_rand); % mean ratio
rmcv_train = mean(rcv_train); % mean ratio
end