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roi_connect.m
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roi_connect.m
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% roi_connect() - compute connectivity between ROIs
%
% Usage:
% EEG = roi_connect(EEG, 'key', 'val', ...);
%
% Inputs:
% EEG - EEGLAB dataset with ROI activity computed
%
% Optional inputs (choose at least one):
% 'morder' - [integer] order of autoregressive model. Default is 20.
% 'naccu' - [integer] number of accumulation for stats. Default is 0.
% 'methods' - [cell] Cell of strings corresponding to methods.
% 'CS' : Cross spectrum
% 'aCOH' : Coherence
% 'cCOH' : (complex-valued) coherency
% 'iCOH' : absolute value of the imaginary part of coherency
% 'GC' : Granger Causality
% 'TRGC' : Time-reversed Granger Causality
% 'wPLI' : Weighted Phase Lag Index
% 'PDC' : Partial directed coherence
% 'TRPDC' : Time-reversed partial directed coherence
% 'DTF' : Directed transfer entropy
% 'TRDTF' : Time-reversed directed transfer entropy
% 'MIM' : Multivariate Interaction Measure for each ROI
% 'MIC' : Maximized Imaginary Coherency for each ROI
% 'freqresolution' - [integer] Desired frequency resolution (in number of frequencies). If
% specified, the signal is zero padded accordingly.
% Default is 0 (means no padding).
% 'roi_selection' - [cell array of integers] Cell array of ROI indices {1, 2, 3, ...} indicating for which regions (ROIs) connectivity should be computed.
% Default is empty (in this case, connectivity will be computed for all ROIs).
%
% Output:
% EEG - EEG structure with EEG.roi field updated and now containing
% connectivity information.
% Copyright (C) Arnaud Delorme, arnodelorme@gmail.com
%
% Redistribution and use in source and binary forms, with or without
% modification, are permitted provided that the following conditions are met:
%
% 1. Redistributions of source code must retain the above copyright notice,
% this list of conditions and the following disclaimer.
%
% 2. Redistributions in binary form must reproduce the above copyright notice,
% this list of conditions and the following disclaimer in the documentation
% and/or other materials provided with the distribution.
%
% THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS"
% AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
% IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
% ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDER OR CONTRIBUTORS BE
% LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
% CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
% SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
% INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
% CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
% ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF
% THE POSSIBILITY OF SUCH DAMAGE.
function EEG = roi_connect(EEG, varargin)
if nargin < 2
help roi_connect;
return
end
if ~isfield(EEG, 'roi') || ~isfield(EEG.roi, 'source_roi_data')
error('Cannot find ROI data - compute ROI data first');
else
source_roi_data = EEG.roi.source_roi_data;
end
% decode input parameters
% -----------------------
g = finputcheck(varargin, { ...
'morder' 'integer' { } 20;
'naccu' 'integer' { } 0;
'methods' 'cell' { } { };
'freqresolution' 'integer' { } 0;
'roi_selection' 'cell' { } { } }, 'roi_connect');
if ischar(g), error(g); end
if isempty(g.naccu), g.naccu = 0; end
% tmpMethods = setdiff(g.methods, { 'CS' 'COH' 'cCOH' 'aCOH' 'iCOH' 'GC' 'TRGC' 'wPLI' 'PDC' 'TRPDC' 'DTF' 'TRDTF' 'MIM' 'MIC' 'PAC'});
% if ~isempty(tmpMethods)
% error('Unknown methods %s', vararg2str(tmpMethods))
% end
inds = {}; ninds = 0;
if isempty(g.roi_selection)
nROI = EEG.roi.nROI;
else
nROI = length(g.roi_selection);
end
nPCA = EEG.roi.nPCA;
for iroi = 1:nROI
for jroi = (iroi+1):nROI
inds{ninds+1} = {(iroi-1)*nPCA + [1:nPCA], (jroi-1)*nPCA + [1:nPCA]};
ninds = ninds + 1;
end
end
if ~isempty(intersect(g.methods, {'COH'}))
warning("'COH' is not supported anymore and will be replaced with 'aCOH' (coherence). " + ...
"Please double-check with the documentation if this is what you really want.")
coh_idx = strcmpi(g.methods, 'COH');
g.methods{coh_idx} = 'aCOH';
end
% wPLI, MIC, MIM, GC and TRGC use data2strcgmim, remaining metrics use data2spwctrgc
methodset1 = { 'wPLI' 'MIM' 'MIC' 'GC' 'TRGC' };
methodset2 = { 'CS' 'aCOH' 'iCOH' 'cCOH' 'PSD' 'PSDROI' 'PDC' 'TRPDC' 'DTF' 'TRDTF' };
tmpMethods1 = intersect(g.methods, methodset1);
if ~isempty(tmpMethods1)
if isempty(g.roi_selection)
conn_mult = data2sctrgcmim(source_roi_data, EEG.roi.pnts, g.morder, 0, g.naccu, [], inds, tmpMethods1, [], 'freqresolution', g.freqresolution);
elseif ~isempty(g.roi_selection)
conn_mult = data2sctrgcmim(source_roi_data, EEG.roi.pnts, g.morder, 0, g.naccu, [], inds, tmpMethods1, [], 'freqresolution', g.freqresolution, 'roi_selection', g.roi_selection, 'nPCA', nPCA);
EEG.roi.roi_selection = g.roi_selection;
end
fields = fieldnames(conn_mult);
for iField = 1:length(fields)
EEG.roi.(fields{iField}) = conn_mult.(fields{iField});
end
% rearrange matrices
if isempty(g.roi_selection)
nROI = EEG.roi.nROI;
else
nROI = length(g.roi_selection);
end
for iMethods = 1:length(tmpMethods1)
if strcmpi(tmpMethods1{iMethods}, 'MIM') || strcmpi(tmpMethods1{iMethods}, 'MIC')
MI = EEG.roi.(tmpMethods1{iMethods})(:, :);
EEG.roi.(tmpMethods1{iMethods}) = get_connect_mat( MI, nROI, +1);
elseif strcmpi(tmpMethods1{iMethods}, 'GC') || strcmpi(tmpMethods1{iMethods}, 'TRGC')
TRGCnet = EEG.roi.(tmpMethods1{iMethods})(:, :, 1) - EEG.roi.(tmpMethods1{iMethods})(:, :, 2);
EEG.roi.(tmpMethods1{iMethods}) = get_connect_mat( TRGCnet, nROI, -1);
else % wPLI
warning(strcat("Only the first principal component will be used to determine ", tmpMethods1{iMethods}))
measure = rm_components(EEG.roi.(tmpMethods1{iMethods}), EEG.roi.nPCA); % only keep the first principal component
EEG.roi.(tmpMethods1{iMethods}) = measure;
end
end
end
tmpMethods2 = intersect(g.methods, methodset2);
if ~isempty(tmpMethods2)
if isempty(g.roi_selection)
conn_mult = data2spwctrgc(source_roi_data, EEG.roi.pnts, g.morder, 0, g.naccu, [], tmpMethods2, [], 'freqresolution', g.freqresolution);
else
conn_mult = data2spwctrgc(source_roi_data, EEG.roi.pnts, g.morder, 0, g.naccu, [], tmpMethods2, [], 'freqresolution', g.freqresolution, 'roi_selection', g.roi_selection, 'nPCA', nPCA);
end
fields = fieldnames(conn_mult);
for iField = 1:length(fields)
EEG.roi.(fields{iField}) = conn_mult.(fields{iField});
end
% only keep the first principal component
for iMethods = 1:length(tmpMethods2)
warning(strcat("Only the first principal component will be used to determine ", tmpMethods2{iMethods}))
measure = rm_components(EEG.roi.(tmpMethods2{iMethods}), EEG.roi.nPCA); % only keep the first principal component
EEG.roi.(tmpMethods2{iMethods}) = measure;
end
end
end