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roi_networkplot.m
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roi_networkplot.m
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% roi_networkplot() - multiple calls to plotconnectivity
%
% Usage:
% [imgFile, txtFile] = roi_networkplot(EEG, networkdefs, measure, 'key', val);
%
% Input:
% EEG - EEGLAB structure with connectivity pre-calculated
% using pop_roi_connectplot
% networkdefs - [string|struct] network definition file (same input as
% roi_definenetwork()). Alternatively network structure
% (second output of roi_definenetwork())
% attempts to use EEG.roi.atlas.networks
% measure - [string] measure to plot. Same as pop_roi_connectplot()
% Alternatively, cell array of connectivity matrices one
% per network.
%
% Optional inputs:
% 'freqrange' - [min max] frequency range in Hz. Default is to plot broadband power.
% 'subplots' - ['on'|'off'] create subplots (when more than one plot).
% Default is 'off'.
% 'exportmean' - ['on'|'off'] export results as text files (when filename defined)
% Default is 'on'.
% 'exportstd' - ['on'|'off'] export results as text files (when filename defined)
% Default is 'on'.
% 'title' - ['string'] figure title. Default none.
% 'plotmode' - ['2D'|'3D'|'both'] figure plotting mode. Default is '2D'
% 'filename' - ['string'] base file name (without extension). This is
% used to save a variety of files with different postfix.
% Default is empty and no file are saved.
%
% Outputs:
% EEG - modified EEG structure
% imgFile - Image file list
% txtFile - Text file list
%
% Example:
% % Compute ROI connectivity
% EEG = pop_dipfit_settings( EEG ); % select boundary element model
% EEG = pop_leadfield(EEG, 'sourcemodel','dipfit/LORETA-Talairach-BAs.mat','sourcemodel2mni',[],'downsample',1);
% EEG = pop_roi_activity(EEG, 'resample','on','regepochs','on','leadfield',EEG.dipfit.sourcemodel,...
% 'model','LCMV','modelparams',{0.05},'atlas','LORETA-Talairach-BAs','nPCA',3);
% EEG = pop_roi_connect(EEG, 'methods', { 'CS'});
%
% % Define a single network and plot it
% DNM = { '25L' '25R' '32L' '32R' '33L' '33R' '23L' '23R' '31L' '31R' '39L' '39R' }';
% [EEG, net] = roi_definenetwork(EEG, table(DNM));
% roi_networkplot(EEG, net, 'crossspecimag', 'freqrange', [8 12]);
%
% See also: roi_plotbrainmovie() and plotconnectivity()
%
% Author: Arnaud Delorme
% Copyright (C) Arnaud Delorme, [email protected]
%
% 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.
% or structure containing the
% fields:
% - chanlocs (from EEG.chanlocs)
% - loreta_P (from EEG.roi.P_eloreta)
% - roiStruct (structure from Scouts EEG.roi.atlas.Scouts(:))
% - networks(x).name (name of network x)
% - networks(x).ROI_inds (indices of ROIs for network x)
function [EEG,imgFileName,txtFileName,measures] = roi_networkplot(EEG, networks, measure, varargin)
if nargin < 2
help roi_networkplot;
return
end
[g, addopts] = finputcheck(varargin, { ...
'subplots' 'string' {'on' 'off'} 'off';
'exportmean' 'string' {'on' 'off'} 'on';
'exportstd' 'string' {'on' 'off'} 'off';
'title' 'string' {} '';
'netstat' 'string' {'on' 'off'} 'off';
'addrois' '' {} [];
'columns' 'integer' {} [];
'limits' 'float' {} [];
'plotmode' 'string' {'2D' '3D' 'both' 'none' } '2D';
'plotopt' 'cell' {} {};
'filename' 'string' {} '';
'threshold' {'string' 'float'} { {} {} } 0.1;
'precomputed' 'struct' {} struct([]);
}, 'roi_networkplot', 'ignore');
if isstr(g)
error(g);
end
if ischar(g.threshold) || isstring(g.threshold)
g.threshold = str2double(g.threshold);
end
if ~isempty(g.filename) % remove file extension
[filePath,g.filename] = fileparts(g.filename);
g.filename = fullfile(filePath, g.filename);
end
if strcmpi(g.subplots, 'on')
if ~strcmpi(g.plotmode, '2D')
error('When using subplots, you cannot use 3-D plots');
end
end
if ~strcmpi(g.plotmode, '2D')
if ~exist('roi_plotbrainmovie')
error('You need to install the Brainmovie plugin to plot sources in 3-D');
end
end
if ~isfield(EEG, 'roi')
error('"roi" field not present in EEG structure, use pop_roi_activity to compute ROI activity');
end
if ~isfield(EEG.roi, 'atlas')
error('"roi.atlas" field not present in EEG structure, use pop_leadfield to use a source model with an atlas');
end
% decode network param
if isempty(networks)
if ~isfield(EEG.roi.atlas, 'networks')
error('"roi.atlas.networks" field not found in EEG structure, use roi_definenetworks to define networks');
end
networks = EEG.roi.atlas.networks;
end
% legacy code reading reading saved network
if ischar(networks)
try
networks = load('-mat', networks);
catch
end
end
% get value of matrix based on measure for the frequency of interest
% ------------------------------------------------------------------
fprintf('Thresold of %s (all connectivity values below the threshold are removed)\n', num2str(g.threshold));
if ischar(measure) % measure contains the name of the measure
matrix = pop_roi_connectplot(EEG, 'measure', measure, 'noplot', 'on', addopts{:});
elseif iscell(measure) % measure contains connectivity matrices
if length(measure) ~= length(networks)
error('When a cell array, "measure" should have as many element as networks');
end
if ~isempty(addopts)
error('Unknown option "%s"', addopts{1});
end
matrix = measure;
else
matrix = measure;
end
% get network and convert if necessary
% ------------------------------------
if isstruct(networks) % in case network is already converted from a table to a structure
[EEG,~,matrix] = roi_definenetwork(EEG, [], 'addrois', g.addrois, 'connectmat', matrix, 'ignoremissing', 'on');
else
[EEG,networks,matrix] = roi_definenetwork(EEG, networks, 'addrois', g.addrois, 'connectmat', matrix, 'ignoremissing', 'on');
end
networks(cellfun(@(x)(length(x) < 2), { networks.ROI_inds })) = []; % Remove networks with less than 2 brain areas
if strcmpi(g.subplots, 'on')
if isempty(g.columns)
ncol = ceil(sqrt(length(networks)));
else
ncol = g.columns;
end
nrow = ceil(length(networks)/ncol);
figure('position', [100 100 350*ncol 350*nrow], 'paperpositionmode', 'auto');
end
imgFileName = {};
txtFileName = {};
roiStruct = EEG.roi.atlas.Scouts(:);
if length(g.threshold) < length(networks)
g.threshold = g.threshold*ones(1,length(networks));
end
sumVals = {};
for iNet = 1:length(networks)
if length(networks(iNet).ROI_inds) < 2
error('Cannot plot network %s: you need at least two brain areas to make a network', length(networks(iNet).ROI_inds));
end
% create structure containing connectivity for the network of interest
if iscell(matrix)
networkMatSubj = matrix{iNet};
if size(networkMatSubj,1) ~= size(networks(iNet).ROI_inds,1)
try
networkMatSubj = networkMatSubj(networks(iNet).ROI_inds, networks(iNet).ROI_inds, :);
catch
error('When a cell array, "measure" should contain matrices which have the same number of elements as the corresponding network');
end
end
else
networkMatSubj = matrix(networks(iNet).ROI_inds, networks(iNet).ROI_inds, :);
end
if 0
% sum
sumVals{iNet} = nansum(nansum(networkMatSubj,1),2);
elseif 0
% max
sumVals{iNet} = nanmax(nanmax(networkMatSubj,[],1),[],2);
else
% median
tmp = networkMatSubj;
for i1 = 1:size(tmp,1)
for i2 = 1:size(tmp,3)
tmp(i1,i1,i2) = NaN;
end
end
tmp = reshape(tmp, size(tmp,1)*size(tmp,2), size(tmp,3));
sumVals{iNet} = nanmedian(tmp, 1);
end
networkMat = mean(networkMatSubj,3);
networkMatStd = std(networkMatSubj,[],3);
if ~strcmpi(g.plotmode, 'none')
if strcmpi(g.subplots, 'on')
subplot(nrow, ncol, iNet)
else
figure('position', [100 100 400 700], 'paperpositionmode', 'auto');
end
end
labels = { roiStruct(networks(iNet).ROI_inds).Label };
tmpTitle = networks(iNet).name;
tmpTitle(tmpTitle == '_') = ' ';
tmpTitle = [ tmpTitle ' ' g.title ];
% 2-D plot
if strcmpi(g.plotmode, '2D') || strcmpi(g.plotmode, 'both')
plotconnectivity(networkMat(:,:), 'labels', labels, 'axis', gca, 'threshold', g.threshold(iNet), 'limits', g.limits, g.plotopt{:});
h = title(tmpTitle, 'interpreter', 'none');
pos = get(h, 'position');
set(h, 'position', pos + [0 0.1 0]);
% save individual plots
if ~strcmpi(g.subplots, 'on') && ~isempty(g.filename)
set(h, 'fontsize', 16, 'fontweight', 'bold');
tmpFileName = [ g.filename '_' networks(iNet).name '.jpg' ];
imgFileName{end+1} = tmpFileName;
print('-djpeg', tmpFileName );
close
end
end
% 3-D plot
if strcmpi(g.plotmode, '3D') || strcmpi(g.plotmode, 'both')
options = {'brainmovieopt' { 'moviename' '' } g.plotopt{:} };
if ~strcmpi(g.subplots, 'on') && ~isempty(g.filename)
tmpFileName = [ g.filename '_' networks(iNet).name '_3d' ];
options = { options{:} 'filename' tmpFileName };
imgFileName{end+1} = [ tmpFileName '.xhtml' ];
end
roi_plotbrainmovie(networkMat(:,:), 'labels', labels, 'threshold', g.threshold(iNet), options{:});
end
% save text
if strcmpi(g.exportmean, 'on') && ~isempty(g.filename)
tmptable = array2table(networkMat(:,:), 'variablenames', labels, 'rownames', labels);
tmpFileName = [ g.filename '_' networks(iNet).name '_mean.txt' ];
txtFileName{end+1} = tmpFileName;
writetable(tmptable, tmpFileName,'WriteRowNames', true );
end
if strcmpi(g.exportstd, 'on') && ~isempty(g.filename)
tmptable = array2table(networkMatStd(:,:), 'variablenames', labels, 'rownames', labels);
tmpFileName = [ g.filename '_' networks(iNet).name '_std.txt' ];
txtFileName{end+1} = tmpFileName;
writetable(tmptable, tmpFileName,'WriteRowNames', true );
end
if nargin > 2
tmpTitle(tmpTitle == ' ') = '_';
tmpTitle(tmpTitle == '.') = '_';
tmpTitle(tmpTitle == '-') = '_';
measures.(tmpTitle).mean = networkMat;
measures.(tmpTitle).labels = labels;
end
end
% perform some stats
if length(networks) > 1 && length(sumVals) == 2 && length(sumVals{1}) == length(sumVals{2})
[H,P,CI,STATS] = ttest(sumVals{1}, sumVals{2});
if P< 0.05
fprintf(2, 'Network %s effect size %1.2f p-value: %1.3f\n', networks(end).name, STATS.tstat, P);
else
fprintf('Network %s effect size %1.2f p-value: %1.3f\n', networks(end).name, STATS.tstat, P);
end
%[ef,~,pvals] = statcond(sumVals(1:2), 'mode', 'perm');
%fprintf('Network %s effect size %1.2f p-value: %1.3f\n', networks(end).name, ef, pvals);
end
% if strcmpi(g.subplots, 'on') && ~isempty(g.title)
% h = textsc(g.title, 'title');
% set(h, 'fontsize', 16, 'fontweight', 'bold');
% end
if strcmpi(g.subplots, 'on') && ~isempty(g.filename)
print('-djpeg', g.filename);
close
end