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ft_detect_movement.m
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ft_detect_movement.m
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function [cfg, movement] = ft_detect_movement(cfg, data)
% FT_SACCADE_DETECTION performs detection of movements such as saccades and
% microsaccades, but also joystick movements, from time series data over multiple
% trials. Different methods for detecting movements are implemented, which are
% described in detail below:
%
% VELOCITY2D - detects micro/saccades using a two-dimensional (2D) velocity according
% to "Engbert R, Kliegl R (2003) Vision Res 43:1035-1045". The vertical and the
% horizontal eyetracker time series (for one eye) are transformed into velocities and
% microsaccades are indentified as "outlier" eye movements that exceed a given
% threshold for velocity and duration. This method has the additional options
% cfg.velocity2D.kernel = vector 1 x nsamples, kernel to compute velocity (default = [1 1 0 -1 -1].*(data.fsample/6);
% cfg.velocity2D.demean = 'no' or 'yes', whether to apply centering correction (default = 'yes')
% cfg.velocity2D.mindur = minimum microsaccade durantion in samples (default = 3);
% cfg.velocity2D.velthres = threshold for velocity outlier detection (default = 6);
%
% CLUSTERING - detects movements according to "Otero-Millan et al., (2014) J Vis 14".
%
% Use as
% [cfg, movement] = ft_detect_movement(cfg, data)
% where the input data should be organised in a structure as obtained from the
% FT_PREPROCESSING function.
%
% The configuration can contain the following options
% cfg.method = string representing the method for movement detection
% 'velocity2D' detects microsaccades using the 2D velocity
% 'clustering' use unsupervised clustering method to detect microsaccades
% cfg.channel = Nx1 cell-array with selection of channels, see FT_CHANNELSELECTION for details, (default = 'all')
% cfg.trials = 'all' or a selection given as a 1xN vector (default = 'all')
%
% The output argument "movement" is a Nx3 matrix. The first and second columns
% specify the begining and end samples of a movement period (saccade, joystick, ...),
% and the third column contains the peak velocity/acceleration movement. The thrid
% column allows to convert movements into spike data representation, making it
% compatible with the spike toolbox functions.
%
% 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_DATABROWSER, FT_DATATYPE_SPIKE
% Copyright (C) 2014, Diego Lozano-Soldevilla
%
% 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/>.
%
% $Id$
% FIXME the help mentioned the
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
% the initial part deals with parsing the input options and data
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
% 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 data
ft_preamble provenance data
ft_preamble trackconfig
% ensure that the input data is valid for this function, this will also do
% backward-compatibility conversions of old data that for example was
% read from an old *.mat file
data = ft_checkdata(data, 'datatype', {'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
% set the defaults
cfg.method = ft_getopt(cfg, 'method', 'velocity2D');
cfg.feedback = ft_getopt(cfg, 'feedback', 'yes');
if isfield(data, 'fsample')
fsample = getsubfield(data, 'fsample');
else
fsample = 1./(mean(diff(data.time{1})));
end
% set the defaults for the various microsaccade detection methods
switch cfg.method
case 'velocity2D'
% Engbert R, Kliegl R (2003) Microsaccades uncover the orientation of
% covert attention. Vision Res 43:1035-1045.
kernel = [1 1 0 -1 -1].*(fsample/6); % this is equivalent to Engbert et al (2003) Vis Res, eqn. (1)
if ~isfield(cfg.velocity2D, 'kernel'), cfg.velocity2D.kernel = kernel; end
if ~isfield(cfg.velocity2D, 'demean'), cfg.velocity2D.demean = 'yes'; end
if ~isfield(cfg.velocity2D, 'mindur'), cfg.velocity2D.mindur = 3; end % minimum microsaccade duration in samples
if ~isfield(cfg.velocity2D, 'velthres'), cfg.velocity2D.velthres = 6; end
case 'clustering'
ft_error('not implemented yet');
% Otero-Millan J, Castro JLA, Macknik SL, Martinez-Conde S (2014)
% Unsupervised clustering method to detect microsaccades. J Vis 14.
otherwise
ft_error('unsupported option for cfg.method');
end % switch method
% select channels and trials of interest, by default this will select all channels and trials
tmpcfg = keepfields(cfg, {'trials', 'channel', 'tolerance', 'showcallinfo', 'trackcallinfo', 'trackconfig', 'trackusage', 'trackdatainfo', 'trackmeminfo', 'tracktimeinfo'});
data = ft_selectdata(tmpcfg, data);
[cfg, data] = rollback_provenance(cfg, data);
% determine the size of the data
ntrial = length(data.trial);
nchan = length(data.label); % number of channels
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
% the actual computation is done in the middle part
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
movement = [];
ft_progress('init', cfg.feedback, 'processing trials');
% do all the computations
for i=1:ntrial
ft_progress(i/ntrial, 'finding microsaccades trial %d of %d\n', i, ntrial);
dat = data.trial{i};
nsample = size(dat,2);
switch cfg.method
case 'velocity2D'
% demean horizontal and vertical time courses
if strcmp(cfg.velocity2D.demean, 'yes')
dat = ft_preproc_polyremoval(dat, 0, 1, nsample);
end
%% eye velocity computation
% deal with padding
n = size(cfg.velocity2D.kernel,2);
pad = ceil(n/2);
dat = ft_preproc_padding(dat, 'localmean', pad);
% convolution. See Engbert et al (2003) Vis Res, eqn. (1)
if n<100
% heuristic: for large kernel the convolution is faster when done along
% the columns, weighing against the costs of doing the transposition.
% the threshold of 100 is a bit ad hoc.
vel = convn(dat, cfg.velocity2D.kernel, 'same');
else
vel = convn(dat.', cfg.velocity2D.kernel.', 'same').';
end
% cut the eges
vel = ft_preproc_padding(vel, 'remove', pad);
%% microsaccade detection
% compute velocity thresholds as in Engbert et al (2003) Vis Res, eqn. (2)
medianstd = sqrt( median(vel.^2,2) - (median(vel,2)).^2 );
% Engbert et al (2003) Vis Res, eqn. (3)
radius = cfg.velocity2D.velthres*medianstd;
% compute test criterion: ellipse equation
test = sum((vel./radius(:,ones(1,nsample))).^2,1);
sacsmp = find(test>1); % microsaccade's indexing
%% determine microsaccades per trial
% first find eye movements of n-consecutive time points
j = find(diff(sacsmp)==1);
j1 = [j; j+1];
com = intersect(j,j+1);
cut = ~ismember(j1,com);
sacidx = reshape(j1(cut),2,[]);
for k=1:size(sacidx,2)
duration = sacidx(1,k):sacidx(2,k);
if size(duration,2) >= cfg.velocity2D.mindur
% finding peak velocity by Pitagoras
begtrl = sacsmp(duration(1,1));
endtrl = sacsmp(duration(1,end));
[peakvel, smptrl] = max(sqrt(sum(vel(:,begtrl:endtrl).^2,1)));
veltrl = sacsmp(duration(1,smptrl)); % peak velocity microsaccade sample -> important for spike conversion
trlsmp = data.sampleinfo(i,1):data.sampleinfo(i,2);
begsample = trlsmp(1, begtrl); % begining microsaccade sample
endsample = trlsmp(1, endtrl); % end microsaccade sample
velsample = trlsmp(1, veltrl); % velocity peak microsaccade sample
movement(end+1,:) = [begsample endsample velsample];
end
end
case 'clustering'
ft_error('not implemented yet');
% Otero-Millan J, Castro JLA, Macknik SL, Martinez-Conde S (2014)
% Unsupervised clustering method to detect microsaccades. J Vis 14.
otherwise
ft_error('unsupported option for cfg.method');
end % switch method
end % for each trial
ft_progress('close');
ft_postamble trackconfig
ft_postamble provenance
ft_postamble debug
ft_postamble previous data