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ft_eventtiminganalysis.m
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ft_eventtiminganalysis.m
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function [dataout] = ft_eventtiminganalysis(cfg, data)
% FT_EVENTTIMINGANALYSIS computes a model of single trial event- related activity,
% by estimating per trial the latency (and amplitude) of event-related signal
% components.
%
% Use as
% [dataout] = ft_eventtiminganalysis(cfg, data)
% where data is single-channel raw data as obtained by FT_PREPROCESSING
% and cfg is a configuration structure according to
%
% cfg.method = method for estimating event-related activity
% 'aseo', analysis of single-trial ERP and ongoing
% activity (according to Xu et al, 2009)
% 'gbve', graph-based variability estimation
% (according to Gramfort et al, IEEE TBME 2009)
% cfg.channel = Nx1 cell-array with selection of channels (default = 'all'),
% see FT_CHANNELSELECTION for details
% cfg.trials = 'all' or a selection given as a 1xN vector (default = 'all')
% cfg.output = 'model', or 'residual', which returns the modelled data,
% or the residuals.
%
% Method specific options are specified in the appropriate substructure.
%
% For the ASEO method, the following options can be specified:
% cfg.aseo.noiseEstimate = 'non-parametric' or 'parametric', estimate noise
% using parametric or non-parametric (default) method
% cfg.aseo.tapsmofrq = value, smoothing parameter of noise for
% nonparametric estimation (default = 5)
% cfg.aseo.jitter = value, time jitter in initial timewindow
% estimate (in seconds). default 0.050 seconds
% cfg.aseo.numiteration = value, number of iteration (default = 1)
% cfg.aseo.initlatency = Nx2 matrix, initial set of latencies in seconds of event-
% related components, give as [comp1start, comp1end;
% comp2start, comp2end] (default not
% specified). For multiple channels it should
% be a cell-array, one matrix per channel
% Alternatively, rather than specifying a (set of latencies), one can also
% specify:
%
% cfg.aseo.initcomp = vector, initial estimate of the waveform
% components. For multiple channels it should
% be a cell-array, one matrix per channel.
%
% For the GBVE method, the following options can be specified:
% cfg.gbve.sigma = vector, range of sigma values to explore in
% cross-validation loop (default: 0.01:0.01:0.2)
% cfg.gbve.distance = scalar, distance metric to use as
% evaluation criterion, see plugin code for
% more informatoin
% cfg.gbve.alpha = vector, range of alpha values to explor in
% cross-validation loop (default: [0 0.001 0.01 0.1])
% cfg.gbve.exponent = scalar, see plugin code for information
% cfg.gbve.use_maximum = boolean, (default: 1) consider the positive going peak
% cfg.gbve.show_pca = boolean, see plugin code (default 0)
% cfg.gbve.show_trial_number = boolean, see plugin code (default 0)
% cfg.gbve.verbose = boolean (default: 1)
% cfg.gbve.disp_log = boolean, see plugin code (default 0)
% cfg.gbve.latency = vector [min max], latency range in s
% (default: [-inf inf])
% cfg.gbve.xwin = scalar smoothing parameter for moving
% average smoothing (default: 1), see
% eeglab's movav function for more
% information.
%
% 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_SINGLETRIALANALYSIS_ASEO
% Copyright (C) 2018-2019, Jan-Mathijs Schoffelen DCCN
%
% 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/>.
%
% $Id$
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 data
ft_preamble provenance data
% the ft_abort variable is set to true or false in ft_preamble_init
if ft_abort
% do not continue function execution in case the outputfile is present and the user indicated to keep it
return
end
% ensure that the input data is valid for this function
data = ft_checkdata(data, 'datatype', {'raw+comp', 'raw'}, 'feedback', 'yes', 'hassampleinfo', 'yes');
% check if the input cfg is valid for this function
cfg = ft_checkconfig(cfg, 'forbidden', {'channels', 'trial'}); % prevent accidental typos, see issue 1729
cfg = ft_checkconfig(cfg, 'required', {'method'});
% set the defaults
cfg.trials = ft_getopt(cfg, 'trials', 'all', 1); % all trials as default
cfg.channel = ft_getopt(cfg, 'channel', 'all');
cfg.output = ft_getopt(cfg, 'output', 'model');
% ensure that the options are valid
cfg = ft_checkopt(cfg, 'method', 'char', {'aseo' 'gbve'});
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
% the actual computation is done in the middle part
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
% select trials of interest
tmpcfg = keepfields(cfg, {'trials' 'channel' 'showcallinfo', 'trackcallinfo', 'trackusage', 'trackdatainfo', 'trackmeminfo', 'tracktimeinfo', 'checksize'});
data = ft_selectdata(tmpcfg, data);
% restore the provenance information
[cfg, data] = rollback_provenance(cfg, data);
% some error checks
if isfield(data, 'trial') && numel(data.trial)==0, ft_error('no trials were selected'); end
if numel(data.label)==0, ft_error('no channels were selected'); end
switch cfg.method
case 'aseo'
% define general variables that are used locally
fsample = data.fsample; % Sampling Frequency in Hz
nchan = numel(data.label);
nsample = numel(data.time{1}); %FIXME ASSUMING FIXED TIME AXIS ACROSS ALL TRIALS
% setting a bunch of options, to be passed on to the lower level function
if ~isfield(cfg, 'aseo'), cfg.aseo = []; end
cfg.aseo.thresholdAmpH = ft_getopt(cfg.aseo, 'thresholdAmpH', 0.5);
cfg.aseo.thresholdAmpL = ft_getopt(cfg.aseo, 'thresholdAmpL', 0.1);
cfg.aseo.thresholdCorr = ft_getopt(cfg.aseo, 'thresholdCorr', 0.2);
cfg.aseo.maxOrderAR = ft_getopt(cfg.aseo, 'maxOrderAR', 5);
cfg.aseo.noiseEstimate = ft_getopt(cfg.aseo, 'noiseEstimate', 'nonparametric');
cfg.aseo.numiteration = ft_getopt(cfg.aseo, 'numiteration', 1);
cfg.aseo.tapsmofrq = ft_getopt(cfg.aseo, 'tapsmofrq', 5);
cfg.aseo.fsample = fsample;
cfg.aseo.nsample = nsample;
cfg.aseo.pad = ft_getopt(cfg.aseo, 'pad', (2.*nsample)/fsample);
% deal with the different ways with which the initial waveforms can be defined
initlatency = ft_getopt(cfg.aseo, 'initlatency', {});
initcomp = ft_getopt(cfg.aseo, 'initcomp', {});
jitter = ft_getopt(cfg.aseo, 'jitter', 0.050); % half temporal width of shift in s
if isempty(initlatency) && isempty(initcomp)
ft_error('for the ASEO method you should supply either an initial estimate of the waveform component, or a set of latencies');
elseif ~isempty(initlatency)
% this takes precedence, and should contain per channel the begin and
% end points of the subwindows in time, based on which the initial
% subcomponents are estimated
% ensure it to be a cell-array if the input is a matrix
if ~iscell(initlatency)
initlatency = repmat({initlatency},[1 nchan]);
end
make_init = true;
elseif ~isempty(initcomp)
% ensure it to be a cell-array if the input is a matrix
if ~iscell(initcomp)
initcomp = repmat({initcomp}, [1 nchan]);
end
make_init = false;
end
if make_init
assert(numel(initlatency)==nchan);
for k = 1:nchan
% preprocessing data
tmp = cellrowselect(data.trial,k);
chandat = cat(1,tmp{:});
chandat = ft_preproc_baselinecorrect(chandat, nearest(data.time{1}, -inf), nearest(data.time{1}, 0));
avgdat = nanmean(chandat, 1);
% set the initial ERP waveforms according to the preset parameters
ncomp = size(initlatency{k},1);
initcomp{k} = zeros(nsample, ncomp);
for m = 1:ncomp
begsmp = nearest(data.time{1},initlatency{k}(m, 1));
endsmp = nearest(data.time{1},initlatency{k}(m, 2));
if begsmp<1, begsmp = 1; end
if endsmp>nsample, endsmp = nsample; end
tmp = avgdat(begsmp:endsmp)';
initcomp{k}(begsmp:endsmp, m) = tmp;
end
initcomp{k} = initcomp{k} - repmat(mean(initcomp{k}),nsample,1);
end
else
assert(numel(initcomp)==nchan);
end
if ~iscell(jitter)
jitter = repmat({jitter}, [1 nchan]);
end
for k = 1:numel(jitter)
if ~isempty(jitter{k})
if size(jitter{k},1)~=size(initcomp{k},2), jitter{k} = repmat(jitter{k}(1,:),[size(initcomp{k},2) 1]); end
end
end
% initialize the output data
dataout = removefields(data, 'cfg');
for k = 1:numel(data.trial)
dataout.trial{k}(:) = nan;
end
% initialize the struct that will contain the output parameters
params = struct([]);
% do the actual computations
for k = 1:nchan
% preprocessing data
tmp = cellrowselect(data.trial,k);
chandat = cat(1,tmp{:});
% baseline correction
chandat = ft_preproc_baselinecorrect(chandat, nearest(data.time{1}, -inf), nearest(data.time{1}, 0));
% do zero-padding and FFT to the signal and initial waveforms
npad = cfg.aseo.pad*fsample; % length of data + zero-padding number
nfft = 2.^(ceil(log2(npad)))*2;
initcomp_fft = fft(initcomp{k}, nfft); % Fourier transform of the initial waveform
chandat_fft = fft(chandat', nfft); % Fourier transform of the signal
cfg.aseo.jitter = jitter{k};
output = ft_singletrialanalysis_aseo(cfg, chandat_fft, initcomp_fft);
params(k).latency = output(end).lat_est./fsample;
params(k).amplitude = output(end).amp_est;
params(k).components = output(end).erp_est;
params(k).rejectflag = output(end).rejectflag;
params(k).noise = output(end).noise;
for m = 1:numel(data.trial)
if output(end).rejectflag(m)==0
switch cfg.output
case 'model'
dataout.trial{m}(k,:) = data.trial{m}(k,:)-output(end).residual(:,m)';
case 'residual'
dataout.trial{m}(k,:) = output(end).residual(:,m)';
end
end
end
end
case 'gbve'
ft_hastoolbox('lagextraction', 1);
ft_hastoolbox('eeglab', 1); % because the low-level code might use a specific moving average function from EEGLAB
ft_hastoolbox('cellfunction', 1);
if ~isfield(cfg, 'gbve'), cfg.gbve = []; end
cfg.gbve.NORMALIZE_DATA = ft_getopt(cfg.gbve, 'NORMALIZE_DATA', true);
cfg.gbve.CENTER_DATA = ft_getopt(cfg.gbve, 'CENTER_DATA', false);
cfg.gbve.USE_ADAPTIVE_SIGMA = ft_getopt(cfg.gbve, 'USE_ADAPTIVE_SIGMA', false);
cfg.gbve.sigma = ft_getopt(cfg.gbve, 'sigma', 0.01:0.01:0.2);
cfg.gbve.distance = ft_getopt(cfg.gbve, 'distance', 'corr2');
cfg.gbve.alpha = ft_getopt(cfg.gbve, 'alpha', [0 0.001 0.01 0.1]);
cfg.gbve.exponent = ft_getopt(cfg.gbve, 'exponent', 1);
cfg.gbve.use_maximum = ft_getopt(cfg.gbve, 'use_maximum', 1); % consider the positive going peak
cfg.gbve.show_pca = ft_getopt(cfg.gbve, 'show_pca', false);
cfg.gbve.show_trial_number = ft_getopt(cfg.gbve, 'show_trial_number', false);
cfg.gbve.verbose = ft_getopt(cfg.gbve, 'verbose', true);
cfg.gbve.disp_log = ft_getopt(cfg.gbve, 'disp_log', false);
cfg.gbve.latency = ft_getopt(cfg.gbve, 'latency', [-inf inf]);
cfg.gbve.xwin = ft_getopt(cfg.gbve, 'xwin', 1); % default is a bit of smoothing
cfg.gbve.nfold = ft_getopt(cfg.gbve, 'nfold', 5);
nchan = numel(data.label);
ntrl = numel(data.trial);
tmin = nearest(data.time{1}, cfg.gbve.latency(1));
tmax = nearest(data.time{1}, cfg.gbve.latency(2));
% initialize the struct that will contain the output parameters
dataout = removefields(data, 'cfg');
params = struct([]);
for k = 1:nchan
% preprocessing data
options = cfg.gbve;
fprintf('--- Processing channel %d\n',k);
tmp = cellrowselect(data.trial,k);
chandat = cat(1,tmp{:});
points = chandat(:,tmin:tmax);
% perform a loop across alpha values, cross validation
alphas = options.alpha;
if length(alphas) > 1 % Use Cross validation error if multiple alphas are specified
best_CVerr = -Inf;
K = cfg.gbve.nfold;
disp(['--- Running K Cross Validation (K = ',num2str(K),')']);
block_idx = fix(linspace(1, ntrl, K+1)); % K cross validation
for jj=1:length(alphas)
options.alpha = alphas(jj);
CVerr = 0;
for kk = 1:K
bidx = block_idx(kk):block_idx(kk+1);
idx = 1:ntrl;
idx(bidx) = [];
data_k = chandat(idx,:);
points_k = points(idx,:);
[order,lags] = extractlag(points_k,options);
data_reordered = data_k(order,:);
lags = lags + tmin;
[data_aligned, dum] = perform_realign(data_reordered, data.time{1}, lags);
data_aligned(~isfinite(data_aligned)) = nan;
ep_evoked = nanmean(data_aligned);
ep_evoked = ep_evoked ./ norm(ep_evoked);
data_k = chandat(bidx,:);
data_norm = sqrt(sum(data_k.^2,2));
data_k = diag(1./data_norm)*data_k;
data_k(data_norm==0,:) = 0;
for pp=1:length(bidx)
c = xcorr(ep_evoked,data_k(pp,:));
CVerr = CVerr + max(c(:));
end
end
CVerr = CVerr/ntrl;
if CVerr > best_CVerr
best_CVerr = CVerr;
best_alpha = alphas(jj);
end
end
options.alpha = best_alpha;
end
if options.use_maximum
[order, lags] = extractlag( points, options );
else
[order, lags] = extractlag( -points, options );
end
disp(['---------- Using alpha = ',num2str(options.alpha)]);
data_reordered = chandat(order,:);
lags = lags + tmin;
[data_aligned] = perform_realign(data_reordered, data.time{1}, lags );
data_aligned(~isfinite(data_aligned)) = nan;
[dum, order_inv] = sort(order);
lags_no_order = lags(order_inv);
data_aligned = data_aligned(order_inv,:);
params(k).latency = data.time{1}(lags_no_order)';
switch cfg.output
case 'model'
tmp = mat2cell(data_aligned, ones(1,size(data_aligned,1)), size(data_aligned,2))';
dataout.trial = cellrowassign(dataout.trial, tmp, k);
case 'residual'
% to be done
error('not yet implemented');
end
end
otherwise
ft_error('unsupported method');
end % switch method
dataout.params = params;
dataout.cfg = cfg;
% do the general cleanup and bookkeeping at the end of the function
ft_postamble debug
ft_postamble previous data
ft_postamble provenance dataout
ft_postamble history dataout
ft_postamble savevar dataout