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ft_artifact_ecg.m
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ft_artifact_ecg.m
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function [cfg, artifact] = ft_artifact_ecg(cfg, data)
% FT_ARTIFACT_ECG performs a peak-detection on the ECG-channel. The
% heart activity can be observed in the MEG data as an MCG artifact.
%
% Use as
% [cfg, artifact] = ft_artifact_ecg(cfg)
% with the configuration options
% cfg.dataset
% cfg.headerfile
% cfg.datafile
%
% Alternatively you can use it as
% [cfg, artifact] = ft_artifact_ecg(cfg, data)
%
% In both cases the configuration should also contain
% cfg.trl = structure that defines the data segments of interest. See FT_DEFINETRIAL
% cfg.continuous = 'yes' or 'no' whether the file contains continuous data
% and
% cfg.artfctdef.ecg.channel = Nx1 cell-array with selection of channels, see FT_CHANNELSELECTION for details
% cfg.artfctdef.ecg.pretim = 0.05; pre-artifact rejection-interval in seconds
% cfg.artfctdef.ecg.psttim = 0.3; post-artifact rejection-interval in seconds
% cfg.artfctdef.ecg.method = 'zvalue'; peak-detection method
% cfg.artfctdef.ecg.cutoff = 3; peak-threshold
% cfg.artfctdef.ecg.inspect = Nx1 list of channels which will be shown in a QRS-locked average
%
% The output argument "artifact" is a Nx2 matrix comparable to the
% "trl" matrix of FT_DEFINETRIAL. The first column of which specifying the
% beginsamples of an artifact period, the second column contains the
% endsamples of the artifactperiods.
%
% To facilitate data-handling and distributed computing you can use
% cfg.inputfile = ...
% If you specify this option the input data will be read from a *.mat
% file on disk. This mat files should contain only a single variable named 'data',
% corresponding to the input structure.
%
% See also FT_REJECTARTIFACT, FT_ARTIFACT_CLIP, FT_ARTIFACT_ECG, FT_ARTIFACT_EOG,
% FT_ARTIFACT_JUMP, FT_ARTIFACT_MUSCLE, FT_ARTIFACT_THRESHOLD, FT_ARTIFACT_ZVALUE
% Copyright (C) 2005-2011, 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 provenance
ft_preamble loadvar data
% 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, 'renamed', {'datatype', 'continuous'});
cfg = ft_checkconfig(cfg, 'renamedval', {'continuous', 'continuous', 'yes'});
% this subfield is required
if ~isfield(cfg,'artfctdef'), cfg.artfctdef = []; end
if ~isfield(cfg.artfctdef,'ecg'), cfg.artfctdef.ecg = []; end
cfg.artfctdef = ft_checkconfig(cfg.artfctdef, 'renamed', {'blc', 'demean'});
cfg.artfctdef = ft_checkconfig(cfg.artfctdef, 'renamed', {'blcwindow' 'baselinewindow'});
% set default rejection parameters for eog artifacts if necessary.
if ~isfield(cfg.artfctdef.ecg,'channel'), cfg.artfctdef.ecg.channel = {'ECG'}; end
if ~isfield(cfg.artfctdef.ecg,'method'), cfg.artfctdef.ecg.method = 'zvalue'; end
if ~isfield(cfg.artfctdef.ecg,'cutoff'), cfg.artfctdef.ecg.cutoff = 3; end
if ~isfield(cfg.artfctdef.ecg,'padding'), cfg.artfctdef.ecg.padding = 0.5; end
if ~isfield(cfg.artfctdef.ecg,'inspect'), cfg.artfctdef.ecg.inspect = {'MLT' 'MRT'}; end
if ~isfield(cfg.artfctdef.ecg,'pretim'), cfg.artfctdef.ecg.pretim = 0.05; end
if ~isfield(cfg.artfctdef.ecg,'psttim'), cfg.artfctdef.ecg.psttim = 0.3; end
if ~isfield(cfg.artfctdef.ecg,'mindist'), cfg.artfctdef.ecg.mindist = 0.5; end
if ~isfield(cfg.artfctdef.ecg,'feedback'), cfg.artfctdef.ecg.feedback = 'yes'; end
if ~isfield(cfg, 'headerformat'), cfg.headerformat = []; end
if ~isfield(cfg, 'dataformat'), cfg.dataformat = []; end
if ~strcmp(cfg.artfctdef.ecg.method, 'zvalue'),
error('method "%s" is not applicable', cfg.artfctdef.ecg.method);
end
% the data is either passed into the function by the user or read from file with cfg.inputfile
hasdata = exist('data', 'var');
if ~hasdata
cfg = ft_checkconfig(cfg, 'dataset2files', 'yes');
cfg = ft_checkconfig(cfg, 'required', {'headerfile', 'datafile'});
hdr = ft_read_header(cfg.headerfile,'headerformat', cfg.headerformat);
trl = cfg.trl;
else
data = ft_checkdata(data, 'hassampleinfo', 'yes');
cfg = ft_checkconfig(cfg, 'forbidden', {'dataset', 'headerfile', 'datafile'});
hdr = ft_fetch_header(data);
if isfield(data, 'sampleinfo'),
trl = data.sampleinfo;
for k = 1:numel(data.trial)
trl(k,3) = time2offset(data.time{k}, data.fsample);
end
else
error('the input data does not contain a valid description of the sampleinfo');
end
end
artfctdef = cfg.artfctdef.ecg;
padsmp = round(artfctdef.padding*hdr.Fs);
ntrl = size(trl,1);
artfctdef.trl = trl;
artfctdef.channel = ft_channelselection(artfctdef.channel, hdr.label);
artfctdef.demean = 'yes';
sgnind = match_str(hdr.label, artfctdef.channel);
numecgsgn = length(sgnind);
fltpadding = 0;
if numecgsgn<1
error('no ECG channels selected');
elseif numecgsgn>1
error('only one ECG channel can be selected');
end
% set default cfg.continuous
if ~isfield(cfg, 'continuous')
if hdr.nTrials==1
cfg.continuous = 'yes';
else
cfg.continuous = 'no';
end
end
% read in the ecg-channel and do demean and squaring
if hasdata
tmpcfg = [];
tmpcfg.channel = artfctdef.channel;
ecgdata = ft_preprocessing(tmpcfg, data);
ecg = ecgdata.trial;
end
for j = 1:ntrl
if ~hasdata
ecg{j} = ft_read_data(cfg.datafile, 'header', hdr, 'begsample', trl(j,1), 'endsample', trl(j,2), 'chanindx', sgnind, 'checkboundary', strcmp(cfg.continuous, 'no'), 'dataformat', cfg.dataformat);
currtime = offset2time(trl(j,3), hdr.Fs, size(ecg{j},2));
ecg{j} = preproc(ecg{j}, artfctdef.channel, currtime, artfctdef, fltpadding, fltpadding);
ecg{j} = ecg{j}.^2;
else
ecg{j} = preproc(ecg{j}, artfctdef.channel, ecgdata.time{j}, artfctdef, fltpadding, fltpadding);
ecg{j} = ecg{j}.^2;
end
end
tmp = cell2mat(ecg);
stmp = std(tmp, 0, 2);
mtmp = mean(tmp, 2);
Nsmp = max(trl(:,2));
trace = zeros(1,Nsmp);
% standardise the ecg
for j = 1:ntrl
trace(trl(j,1):trl(j,2)) = (ecg{j}-mtmp)./stmp;
end
accept = strcmp(cfg.artfctdef.ecg.feedback, 'no');
while accept == 0,
h = figure;
plot(trace);zoom;
hold on;
plot([1 Nsmp], [artfctdef.cutoff artfctdef.cutoff], 'r:');
hold off;
xlabel('samples');
ylabel('zscore');
fprintf(['\ncurrent ',artfctdef.method,' threshold = %1.3f'], artfctdef.cutoff);
response = input('\nkeep the current value (y/n) ?\n','s');
switch response
case 'n'
oldcutoff = artfctdef.cutoff;
artfctdef.cutoff = input('\nenter new value \n');
case 'y'
oldcutoff = artfctdef.cutoff;
accept = 1;
otherwise
warning('unrecognised response, assuming no');
oldcutoff = artfctdef.cutoff;
artfctdef.cutoff = input('\nenter new value \n');
end;
close
end
% detect peaks which are at least half a second apart and store
% the indices of the qrs-complexes in the artifact-configuration
mindist = round(cfg.artfctdef.ecg.mindist.*hdr.Fs);
[pindx, pval] = peakdetect2(trace, artfctdef.cutoff, mindist);
%sel = find(standardise(pval,2)<2);
%pindx = pindx(sel);
%pval = pval(sel);
artfctdef.qrs = pindx;
%---------------------------------------
% create trials for qrs-triggered average
trl = [];
trl(:,1) = pindx(:) - round(artfctdef.padding*(hdr.Fs)) ;
trl(:,2) = pindx(:) + round(artfctdef.padding*(hdr.Fs))-1;
trl(:,3) = -round(artfctdef.padding*(hdr.Fs));
trl(trl(:,1)<1,:) = [];
trl(trl(:,2)>hdr.nSamples.*hdr.nTrials,:) = [];
%------------
% ---------------------
% qrs-triggered average
% FIXME, at present this only works for continuous data: the assumption can
% be made that all trials are equally long.
sgn = ft_channelselection(artfctdef.inspect, hdr.label);
megind = match_str(hdr.label, sgn);
sgnind = [megind(:); sgnind];
dat = zeros(length(sgnind), trl(1,2)-trl(1,1)+1);
ntrl = size(trl,1);
if ~isempty(sgnind)
ntrlok = 0;
for j = 1:ntrl
fprintf('reading and preprocessing trial %d of %d\n', j, ntrl);
if ~hasdata
dum = ft_read_data(cfg.datafile, 'header', hdr, 'begsample', trl(j,1), 'endsample', trl(j,2), 'chanindx', sgnind, 'checkboundary', strcmp(cfg.continuous, 'no'), 'dataformat', cfg.dataformat);
dat = dat + ft_preproc_baselinecorrect(dum);
ntrlok = ntrlok + 1;
elseif hasdata
dum = ft_fetch_data(data, 'header', hdr, 'begsample', trl(j,1), 'endsample', trl(j,2), 'chanindx', sgnind, 'checkboundary', strcmp(cfg.continuous, 'no'), 'docheck', 0);
if any(~isfinite(dum(:))),
else
ntrlok = ntrlok + 1;
dat = dat + ft_preproc_baselinecorrect(dum);
end
end
end
end
dat = dat./ntrlok;
time = offset2time(trl(1,3), hdr.Fs, size(dat,2));
tmp = dat(1:end-1,:);
mdat = max(abs(tmp(:)));
acceptpre = strcmp(cfg.artfctdef.ecg.feedback, 'no');
acceptpst = strcmp(cfg.artfctdef.ecg.feedback, 'no');
while acceptpre == 0 || acceptpst == 0,
h = figure;
subplot(2,1,1); plot(time, dat(end, :));
abc = axis;
axis([time(1) time(end) abc(3:4)]);
subplot(2,1,2);
axis([time(1) time(end) -1.1*mdat 1.1*mdat]);
xpos = -artfctdef.pretim;
ypos = -1.05*mdat;
width = artfctdef.pretim + artfctdef.psttim;
height = 2.1*mdat;
rectangle('Position', [xpos ypos width height], 'FaceColor', 'r');
hold on; plot(time, dat(1:end-1, :), 'b');
if acceptpre == 0,
fprintf(['\ncurrent pre-peak interval = %1.3f'], artfctdef.pretim);
response = input('\nkeep the current value (y/n) ?\n','s');
switch response
case 'n'
oldpretim = artfctdef.pretim;
artfctdef.pretim = input('\nenter new value \n');
case 'y'
oldpretim = artfctdef.pretim;
acceptpre = 1;
otherwise
warning('unrecognised response, assuming no');
oldpretim = artfctdef.pretim;
end
end
if acceptpst == 0 && acceptpre == 1,
fprintf(['\ncurrent post-peak interval = %1.3f'], artfctdef.psttim);
response = input('\nkeep the current value (y/n) ?\n','s');
switch response
case 'n'
oldpsttim = artfctdef.psttim;
artfctdef.psttim = input('\nenter new value \n');
case 'y'
oldpsttim = artfctdef.psttim;
acceptpst = 1;
otherwise
warning('unrecognised response, assuming no');
oldpsttim = artfctdef.psttim;
end
end
close
end
artifact(:,1) = trl(:,1) - trl(:,3) - round(artfctdef.pretim*hdr.Fs);
artifact(:,2) = trl(:,1) - trl(:,3) + round(artfctdef.psttim*hdr.Fs);
% remember the details that were used here
cfg.artfctdef.ecg = artfctdef;
cfg.artfctdef.ecg.artifact = artifact;
% do the general cleanup and bookkeeping at the end of the function
ft_postamble provenance
ft_postamble previous data