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ft_connectivityplot.m
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ft_connectivityplot.m
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function [cfg] = ft_connectivityplot(cfg, varargin)
% FT_CONNECTIVITYPLOT plots channel-level frequency resolved connectivity. The
% data are rendered in a square grid of subplots, each subplot containing the
% connectivity spectrum between the two respective channels.
%
% Use as
% ft_connectivityplot(cfg, data)
% where the first input argument is a configuration structure (see below)
% and the input data is a structure obtained from FT_CONNECTIVITYANALYSIS
% using a frequency-domain connectivity metric. Consequently the input data
% should have a dimord of 'chan_chan_freq', or 'chan_chan_freq_time'.
%
% The configuration can have the following options
% cfg.parameter = string, the functional parameter to be plotted (default = 'cohspctrm')
% cfg.xlim = selection boundaries over first dimension in data (e.g., freq)
% 'maxmin' or [xmin xmax] (default = 'maxmin')
% cfg.ylim = selection boundaries over second dimension in data
% (i.e. ,time, if present), 'maxmin', or [ymin ymax]
% (default = 'maxmin')
% cfg.zlim = plotting limits for color dimension, 'maxmin', 'maxabs' or [zmin zmax] (default = 'maxmin')
% cfg.channel = list of channels to be included for the plotting (default = 'all'), see FT_CHANNELSELECTION for details
%
% See also FT_CONNECTIVITYANALYSIS, FT_CONNECTIVITYSIMULATION, FT_MULTIPLOTCC, FT_TOPOPLOTCC
% Copyright (C) 2011-2017, Jan-Mathijs Schoffelen
%
% This file is part of FieldTrip, see http://www.fieldtriptoolbox.org
% for the documentation and details.
%
% FieldTrip is free software: you can redistribute it and/or modify
% it under the terms of the GNU General Public License as published by
% the Free Software Foundation, either version 3 of the License, or
% (at your option) any later version.
%
% FieldTrip is distributed in the hope that it will be useful,
% but WITHOUT ANY WARRANTY; without even the implied warranty of
% MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
% GNU General Public License for more details.
%
% You should have received a copy of the GNU General Public License
% along with FieldTrip. If not, see <http://www.gnu.org/licenses/>.
%
% $Id$
% these are used by the ft_preamble/ft_postamble function and scripts
ft_revision = '$Id$';
ft_nargin = nargin;
ft_nargout = nargout;
% do the general setup of the function
ft_defaults
ft_preamble init
ft_preamble debug
ft_preamble loadvar varargin
ft_preamble provenance varargin
ft_preamble trackconfig
% the ft_abort variable is set to true or false in ft_preamble_init
if ft_abort
return
end
% check if the input cfg is valid for this function
cfg = ft_checkconfig(cfg, 'forbidden', {'channels'}); % prevent accidental typos, see issue 1729
cfg = ft_checkconfig(cfg, 'renamed', {'zparam', 'parameter'});
cfg = ft_checkconfig(cfg, 'renamed', {'color', 'linecolor'});
cfg = ft_checkconfig(cfg, 'renamed', {'graphcolor', 'linecolor'});
% set the defaults
cfg.channel = ft_getopt(cfg, 'channel', 'all');
cfg.parameter = ft_getopt(cfg, 'parameter', 'cohspctrm');
cfg.zlim = ft_getopt(cfg, 'zlim', 'maxmin');
cfg.ylim = ft_getopt(cfg, 'ylim', 'maxmin');
cfg.xlim = ft_getopt(cfg, 'xlim', 'maxmin');
cfg.linecolor = ft_getopt(cfg, 'linecolor', 'brgkywrgbkywrgbkywrgbkyw');
cfg.linestyle = ft_getopt(cfg, 'linestyle', '-');
cfg.linewidth = ft_getopt(cfg, 'linewidth', 0.5);
cfg.visible = ft_getopt(cfg, 'visible', 'on');
cfg.renderer = ft_getopt(cfg, 'renderer', []); % let MATLAB decide on the default
% check if the input data is valid for this function
% ensure that the input is correct
Ndata = numel(varargin);
dtype = cell(Ndata, 1);
iname = cell(Ndata+1, 1);
for k = 1:Ndata
if ischar(cfg.parameter)
cfg.parameter = repmat({cfg.parameter}, [1 Ndata]);
end
% check whether all requested parameters are the same. If not, rename
% this, because otherwise a call to ft_selectdata (below) won't work
if ~all(strcmp(cfg.parameter,cfg.parameter{1}))
fprintf('different types of connectivity are to be displayed in the same figure\n');
varargin{k}.connectivity = varargin{k}.(cfg.parameter{k});
varargin{k} = rmfield(varargin{k}, cfg.parameter{k});
if isfield(varargin{k}, [cfg.parameter{k} 'dimord'])
varargin{k}.connectivitydimord = varargin{k}.([cfg.parameter{k} 'dimord']);
varargin{k} = rmfield(varargin{k}, [cfg.parameter{k} 'dimord']);
end
cfg.parameter{k} = 'connectivity';
else
% don't worry
end
% check if the input data is valid for this function
varargin{k} = ft_checkdata(varargin{k}, 'datatype', {'timelock', 'freq'});
dtype{k} = ft_datatype(varargin{k});
% convert into the the supported dimord
switch varargin{k}.dimord
case {'chan_chan_freq' 'chan_chan_freq_time'}
% that's ok
case {'chancmb_freq' 'chancmb_freq_time'}
% convert into 'chan_chan_freq'
varargin{k} = ft_checkdata(varargin{k}, 'cmbstyle', 'full');
otherwise
ft_error('the data should have a dimord of %s or %s', 'chan_chan_freq', 'chancmb_freq');
end
% this is needed for correct treatment of linecolor later on
if nargin>1
if ~isempty(inputname(k+1))
iname{k+1} = inputname(k+1);
else
iname{k+1} = ['input',num2str(k, '%02d')];
end
else
% not yet supported
iname{k+1} = cfg.inputfile{k};
end
end
if Ndata >1
if ~all(strcmp(dtype{1}, dtype))
ft_error('input data are of different type; this is not supported');
end
end
if ischar(cfg.linecolor)
% ensure it is a column vector of the right length
cfg.linecolor = repmat(cfg.linecolor(:), ceil(Ndata/length(cfg.linecolor)), 1);
cfg.linecolor = cfg.linecolor(1:Ndata);
elseif isnumeric(cfg.linecolor)
% ensure it is a Nx3 matrix of the right length
cfg.linecolor = repmat(cfg.linecolor, ceil(Ndata/length(cfg.linecolor)), 1);
cfg.linecolor = cfg.linecolor(1:Ndata,:);
end
% ensure that the data in all inputs has the same channels, time-axis, etc.
tmpcfg = keepfields(cfg, {'channel', 'showcallinfo'});
[varargin{:}] = ft_selectdata(tmpcfg, varargin{:});
% restore the provenance information
[cfg, varargin{:}] = rollback_provenance(cfg, varargin{:});
% check presence of time / freq axes
hasfreq = isfield(varargin{1}, 'freq');
hastime = isfield(varargin{1}, 'time');
if hasfreq && hastime
if Ndata>1
ft_error('when the input data contains time-frequency representations, only a single data argument is allowed');
end
xparam = 'time';
yparam = 'freq';
elseif hasfreq
xparam = 'freq';
yparam = '';
elseif hastime
xparam = 'time';
yparam = '';
end
% Get physical min/max range of x:
if ischar(cfg.xlim) && strcmp(cfg.xlim, 'maxmin')
xmin = inf;
xmax = -inf;
for k = 1:Ndata
xmin = min(xmin,varargin{k}.(xparam)(1));
xmax = max(xmax,varargin{k}.(xparam)(end));
end
else
xmin = cfg.xlim(1);
xmax = cfg.xlim(2);
end
cfg.xlim = [xmin xmax];
% Get physical min/max range of y:
if ischar(cfg.ylim) && strcmp(cfg.ylim, 'maxmin') && ~isempty(yparam)
ymin = inf;
ymax = -inf;
for k = 1:Ndata
ymin = min(ymin,varargin{k}.(yparam)(1));
ymax = max(ymax,varargin{k}.(yparam)(end));
end
elseif ~isempty(yparam)
ymin = cfg.ylim(1);
ymax = cfg.ylim(2);
elseif isempty(yparam)
ymin = [];
ymax = [];
end
cfg.ylim = [ymin ymax];
% Get physical min/max range of z, which is the functional data:
if ischar(cfg.zlim) && strcmp(cfg.zlim, 'maxmin')
zmin = inf;
zmax = -inf;
for k = 1:Ndata
zmin = min(zmin,min(varargin{k}.(cfg.parameter{k})(:)));
zmax = max(zmax,max(varargin{k}.(cfg.parameter{k})(:)));
end
elseif ischar(cfg.zlim) && strcmp(cfg.zlim, 'maxabs')
zmax = -inf;
for k = 1:Ndata
zmax = max(zmax,max(abs(varargin{k}.(cfg.parameter{k})(:))));
end
zmin = -zmax;
else
zmin = cfg.zlim(1);
zmax = cfg.zlim(2);
end
cfg.zlim = [zmin zmax];
% make the function recursive if Ndata>1
if Ndata>1
data = varargin{1};
tmpcfg = cfg;
if ischar(cfg.parameter)
% do nothing
elseif iscell(cfg.parameter)
tmpcfg.parameter = cfg.parameter{1};
end
ft_connectivityplot(tmpcfg, data);
tmpcfg = cfg;
if ischar(cfg.linecolor), colorLabels = [iname{2} '=' tmpcfg.linecolor(1) '\n'];
elseif isnumeric(cfg.linecolor), colorLabels = [iname{2} '=' num2str(tmpcfg.linecolor(1, :)) '\n'];
end
for k = 2:Ndata
if ischar(cfg.linecolor), tmpcfg.linecolor = tmpcfg.linecolor(2:end);
else isnumeric(cfg.linecolor),tmpcfg.linecolor = tmpcfg.linecolor(2:end,:);
end
tmpcfg.holdfig = 1;
if ischar(cfg.parameter)
% do nothing
elseif iscell(cfg.parameter)
tmpcfg.parameter = cfg.parameter{k};
end
ft_connectivityplot(tmpcfg, varargin{k});
if ischar(cfg.linecolor); colorLabels = [colorLabels iname{k+1} '=' tmpcfg.linecolor(1) '\n'];
elseif isnumeric(cfg.linecolor); colorLabels = [colorLabels iname{k+1} '=' num2str(tmpcfg.linecolor(1, :)) '\n'];
end
end
ft_plot_text(0.5, (numel(varargin{k}.label)+1).*1.2-0.5, sprintf(colorLabels), 'horizontalalignment', 'right');
return;
else
data = varargin{1};
end
if ~isfield(data, cfg.parameter{1})
ft_error('the data does not contain the requested parameter %s', cfg.parameter{1});
end
% get the selection of the data
tmpcfg = [];
if hasfreq && hastime
tmpcfg.latency = cfg.xlim;
tmpcfg.frequency = cfg.ylim;
elseif hasfreq
tmpcfg.frequency = cfg.xlim;
elseif hastime
tmpcfg.latency = cfg.xlim;
end
data = ft_selectdata(tmpcfg, data);
% restore the provenance information
[cfg, data] = rollback_provenance(cfg, data);
dat = data.(cfg.parameter{k});
nchan = numel(data.label);
if hasfreq, nfreq = numel(data.freq); end
if hastime, ntime = numel(data.time); end
if (isfield(cfg, 'holdfig') && cfg.holdfig==0) || ~isfield(cfg, 'holdfig')
cla;
hold on;
end
for k = 1:nchan
for m = 1:nchan
if k~=m
ix = k;
iy = nchan - m + 1;
% use the convention of the row-channel causing the column-channel
if hastime && hasfreq && ntime>1
tmp = reshape(dat(m,k,:,:), [nfreq ntime]);
ft_plot_matrix(tmp, 'width', 1, 'height', 1, 'hpos', ix.*1.2, 'vpos', iy.*1.2, 'clim', cfg.zlim, 'box', 'yes');
elseif hasfreq
tmp = reshape(dat(m,k,:), [nfreq 1]);
ft_plot_vector(tmp, 'width', 1, 'height', 1, 'hpos', ix.*1.2, 'vpos', iy.*1.2, 'vlim', cfg.zlim, 'box', 'yes', 'color', cfg.linecolor(1,:), 'linewidth', cfg.linewidth, 'style', cfg.linestyle);
elseif hastime
ft_error('plotting data with only a time axis is not supported yet');
end
if k==1
% first column, plot scale on y axis
if hastime && hasfreq && ntime>1
val1 = cfg.ylim(1);
val2 = cfg.ylim(2);
elseif hasfreq
val1 = cfg.zlim(1);
val2 = cfg.zlim(2);
elseif hastime
end
fontsize = 10;
ft_plot_text(ix.*1.2-0.5, iy.*1.2-0.5, num2str(val1,3), 'HorizontalAlignment', 'Right', 'VerticalAlignment', 'Middle', 'FontSize', fontsize);
ft_plot_text(ix.*1.2-0.5, iy.*1.2+0.5, num2str(val2,3), 'HorizontalAlignment', 'Right', 'VerticalAlignment', 'Middle', 'FontSize', fontsize);
end
if m==nchan
% bottom row, plot scale on x axis
fontsize = 10;
ft_plot_text(ix.*1.2-0.5, iy.*1.2-0.5, num2str(cfg.xlim(1),3), 'HorizontalAlignment', 'Center', 'VerticalAlignment', 'top', 'FontSize', fontsize);
ft_plot_text(ix.*1.2+0.5, iy.*1.2-0.5, num2str(cfg.xlim(2),3), 'HorizontalAlignment', 'Center', 'VerticalAlignment', 'top', 'FontSize', fontsize);
end
end
end
end
% add channel labels on grand X and Y axes
for k = 1:nchan
ft_plot_text(0.5, (nchan + 1 - k).*1.2, data.label{k}, 'horizontalalignment', 'right');
ft_plot_text(k.*1.2, (nchan + 1) .*1.2-0.5, data.label{k}, 'horizontalalignment', 'left', 'rotation', 90);
end
% add 'from' and 'to' labels
ft_plot_text(-0.5, (nchan + 1)/1.7, '\it{from}', 'interpreter', 'tex', 'rotation', 90);
ft_plot_text((nchan + 1)/1.7, (nchan + 1)*1.2+0.4, '\it{to}', 'interpreter', 'tex');
axis([-0.2 (nchan+1).*1.2+0.2 0 (nchan+1).*1.2+0.2]);
axis off;
set(gcf, 'color', [1 1 1]);
% this is needed for the figure title
if isfield(cfg, 'dataname') && ~isempty(cfg.dataname)
dataname = cfg.dataname;
elseif isfield(cfg, 'inputfile') && ~isempty(cfg.inputfile)
dataname = cfg.inputfile;
elseif nargin>1
dataname = arrayfun(@inputname, 2:nargin, 'UniformOutput', false);
else
dataname = {};
end
% set the figure window title
if ~isempty(dataname)
set(gcf, 'Name', sprintf('%d: %s: %s', double(gcf), mfilename, join_str(', ', dataname)));
else
set(gcf, 'Name', sprintf('%d: %s', double(gcf), mfilename));
end
set(gcf, 'NumberTitle', 'off');
% do the general cleanup and bookkeeping at the end of the function
ft_postamble debug
ft_postamble trackconfig
ft_postamble previous varargin
ft_postamble provenance
ft_postamble savefig
% add a menu to the figure, but only if the current figure does not have subplots
menu_fieldtrip(gcf, cfg, false);
if ~ft_nargout
% don't return anything
clear cfg
end