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ft_lateralizedpotential.m
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ft_lateralizedpotential.m
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function [lrp] = ft_lateralizedpotential(cfg, avgL, avgR)
% FT_LATERALIZEDPOTENTIAL computes lateralized potentials such as the
% lateralized readiness potential (LRP)
%
% Use as
% [lrp] = ft_lateralizedpotential(cfg, avgL, avgR)
%
% where the input datasets should come from FT_TIMELOCKANALYSIS
% and the configuration should contain
% cfg.channelcmb = Nx2 cell array
%
% An example channelcombination containing the homologous channels
% in the 10-20 standard system is
% cfg.channelcmb = {'Fp1' 'Fp2'
% 'F7' 'F8'
% 'F3' 'F4'
% 'T7' 'T8'
% 'C3' 'C4'
% 'P7' 'P8'
% 'P3' 'P4'
% 'O1' 'O2'}
%
% The lateralized potential is computed on combinations of channels and
% not on indivudual channels. However, if you want to make a topographic
% plot with e.g. FT_MULTIPLOTER, you can replace the output lrp.label
% with lrp.plotlabel.
%
% The concept for the LRP was introduced approximately simultaneously in the
% following two papers
% - M. G. H. Coles. Modern mind-brain reading - psychophysiology,
% physiology, and cognition. Psychophysiology, 26(3):251-269, 1988.
% - R. de Jong, M. Wierda, G. Mulder, and L. J. Mulder. Use of
% partial stimulus information in response processing. J Exp Psychol
% Hum Percept Perform, 14:682-692, 1988.
% and it is discussed in detail on a technical level in
% - R. Oostenveld, D.F. Stegeman, P. Praamstra and A. van Oosterom.
% Brain symmetry and topographic analysis of lateralized event-related
% potentials. Clin Neurophysiol. 114(7):1194-202, 2003.
%
% To facilitate data-handling and distributed computing you can use
% cfg.inputfile = ...
% cfg.outputfile = ...
% If you specify one of these (or both) the input data will be read from a *.mat
% file on disk and/or the output data will be written to a *.mat file. These mat
% files should contain only a single variable, corresponding with the
% input/output structure.
%
% See also FT_TIMELOCKANALYSIS, FT_MULTIPLOTER
% Copyright (C) 2004, Robert Oostenveld
%
% 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 avgL avgR
ft_preamble provenance avgL avgR
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 data is valid for this function
avgL = ft_checkdata(avgL, 'datatype', 'timelock');
avgR = ft_checkdata(avgR, 'datatype', 'timelock');
% set the defaults
if ~isfield(cfg, 'channelcmb'),
cfg.channelcmb = {
'Fp1' 'Fp2'
'F7' 'F8'
'F3' 'F4'
'T7' 'T8'
'C3' 'C4'
'P7' 'P8'
'P3' 'P4'
'O1' 'O2'
};
end
if ~isequal(avgL.time, avgR.time)
error('the time axes are not the same');
end
% start with an empty output structure
lrp.label = {};
lrp.plotlabel = {};
lrp.avg = [];
lrp.time = avgL.time;
% add timelock signature
if isfield(avgL, 'dimord') && isfield(avgR, 'dimord')
if ~strcmp(avgL.dimord, avgR.dimord)
error('The input data are of different dimord types');
else
lrp.dimord = avgL.dimord;
end
else
error('''dimord'' not found. The function expects timelock data');
end
% compute the lateralized potentials
Nchan = size(cfg.channelcmb);
for i=1:Nchan
% here the channel names "C3" and "C4" are used to clarify the
% computation of the lateralized potential on all channel pairs
C3R = strcmp(cfg.channelcmb{i,1}, avgR.label);
C4R = strcmp(cfg.channelcmb{i,2}, avgR.label);
C3L = strcmp(cfg.channelcmb{i,1}, avgL.label);
C4L = strcmp(cfg.channelcmb{i,2}, avgL.label);
if any(C3R) && any(C4R) && any(C3L) && any(C4L)
lrp.label{end+1} = sprintf('%s/%s', cfg.channelcmb{i,1}, cfg.channelcmb{i,2});
lrp.plotlabel{end+1} = cfg.channelcmb{i,1};
erpC3L = avgL.avg(C3L,:);
erpC4L = avgL.avg(C4L,:);
erpC3R = avgR.avg(C3R,:);
erpC4R = avgR.avg(C4R,:);
lrp.avg(end+1,:) = 1/2 * ((erpC3R - erpC4R) + (erpC4L - erpC3L));
end
end
% do the general cleanup and bookkeeping at the end of the function
ft_postamble debug
ft_postamble trackconfig
ft_postamble previous avgL avgR
ft_postamble provenance lrp
ft_postamble history lrp
ft_postamble savevar lrp