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function ft_realtime_headlocalizer(cfg)
% FT_REALTIME_HEADLOCALIZER is a real-time application for online visualization of
% the head position for the CTF275 and the Neuromag/Elekta/Megin systems. This uses the
% continuous head localization (in CTF terminology, i.e. CHL) or position indicator
% (in Neuromag/Elekta/Megin terminology, i.e. cHPI) information.
%
% Repositioning the subject to a previous recording session can be done by specifying
% the previous dataset as cfg.template = 'subject01xxx.ds', or by pointing to a text
% file created during a previous recording; e.g. cfg.template = '29-Apr-2013-xxx.txt'.
% The latter textfile is written automatically to disk with each 'Update' buttonpress.
%
% The online visualization shows the displacement of the head relative to the start
% of the recording. The timepoint (i.e. position) relative to which the displacement
% is shown can be updated can be achieved by marking the HPI at an arbitrary moment
% by clicking the 'Update' button. This allows for repositioning within a recording
% session. Black unfilled markers should appear which indicate the positions of the
% coils at the moment of buttonpress. Distance to these marked positions then become
% colorcoded, i.e. green, orange, or red.
%
% Use as
% ft_realtime_headlocalizer(cfg)
% with the following configuration options
% cfg.dataset = string, name or location of a dataset/buffer (default = 'buffer://odin:1972')
% cfg.template = string, name of a template dataset for between-session repositioning (default = [])
% cfg.bufferdata = whether to start on the 'first or 'last' data that is available (default = 'last')
% cfg.xlim = [min max], range in cm to plot (default = [-15 15])
% cfg.ylim = [min max], range in cm to plot (default = [-15 15])
% cfg.zlim = [min max], range in cm to plot (default is automatic)
% cfg.blocksize = number, size of the blocks/chuncks that are processed (default = 1 second)
% cfg.accuracy_green = distance from fiducial coordinate; green when within limits (default = 0.15 cm)
% cfg.accuracy_orange = orange when within limits, red when out (default = 0.3 cm)
% cfg.dewar = filename or mesh, description of the dewar shape (default is automatic)
% cfg.polhemus = filename or mesh, description of the head shape recorded with the Polhemus (default is automatic)
% cfg.headshape = filename or mesh, description of the head shape recorded with the Structure Sensor
%
% The following options only apply to data from the Neuromag/Elekta/Megin system
% cfg.headmovement = string, name or location of the .pos file created by MaxFilter which describes the location of the head relative to the dewar
% cfg.coilfreq = single number in Hz or list of numbers (default = [293, 307, 314, 321, 328])
%
% This method is described in Stolk A, Todorovic A, Schoffelen JM, Oostenveld R.
% "Online and offline tools for head movement compensation in MEG."
% Neuroimage. 2013 Mar;68:39-48. doi: 10.1016/j.neuroimage.2012.11.047.
% Copyright (C) 2008-2018, Arjen Stolk & Robert Oostenveld
% Copyright (C) 2017, Simon Homoelle
%
% 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/>.
%
% $Id$
agreement = {
'By using this realtime headlocalizer tool in your research, you agree to citing the publication below.'
''
'Stolk A, Todorovic A, Schoffelen JM, Oostenveld R.'
'"Online and offline tools for head movement compensation in MEG."'
'Neuroimage. 2013 Mar;68:39-48.'
};
if ~strcmp(questdlg(agreement, 'User agreement', 'Yes', 'Cancel', 'Cancel'), 'Yes')
return
end
% do the general setup of the function
ft_defaults
% set the defaults
cfg.dataset = ft_getopt(cfg, 'dataset', 'buffer://odin:1972'); % location of the buffer/dataset
cfg.accuracy_green = ft_getopt(cfg, 'accuracy_green', .15); % green when within this distance from reference
cfg.accuracy_orange = ft_getopt(cfg, 'accuracy_orange', .3); % orange when within this distance from reference
cfg.template = ft_getopt(cfg, 'template', []); % template dataset containing the references
cfg.blocksize = ft_getopt(cfg, 'blocksize', 1); % in seconds
cfg.bufferdata = ft_getopt(cfg, 'bufferdata', 'last'); % first (replay) or last (real-time)
cfg.coilfreq = ft_getopt(cfg, 'coilfreq', [293, 307, 314, 321, 328]); % in Hz for Neuromag
cfg.dewar = ft_getopt(cfg, 'dewar', []); % mesh of the dewar
cfg.headshape = ft_getopt(cfg, 'headshape', []); % mesh of the head with the structure sensor
cfg.polhemus = ft_getopt(cfg, 'polhemus', []); % mesh of the head recorded with the polhemus
cfg.headmovement = ft_getopt(cfg, 'headmovement', []); % maxfilter created file containing quaternions information for headlocalistation
% ensure pesistent variables are cleared
clear ft_read_header
% start by reading the header from the realtime buffer
cfg = ft_checkconfig(cfg, 'dataset2files', 'yes'); % translate dataset into datafile+headerfile
hdr = ft_read_header(cfg.headerfile, 'cache', true, 'coordsys', 'dewar');
% for backward compatibility, can be removed end 2018
cfg = ft_checkconfig(cfg, 'renamed', {'head', 'headshape'});
% determine the size of blocks to process
blocksize = round(cfg.blocksize * hdr.Fs);
prevSample = 0;
count = 0;
% determine MEG system type
isneuromag = ft_senstype(hdr.grad, 'neuromag');
isctf = ft_senstype(hdr.grad, 'ctf275');
% this is needed to fit everything in the figure, note that the dewar coordinate systems differ
if isctf
cfg.xlim = ft_getopt(cfg, 'xlim', [-15 15]);
cfg.ylim = ft_getopt(cfg, 'ylim', [-15 15]);
cfg.zlim = ft_getopt(cfg, 'zlim', [-38 -8]);
elseif isneuromag
cfg.xlim = ft_getopt(cfg, 'xlim', [-15 15]);
cfg.ylim = ft_getopt(cfg, 'ylim', [-15 15]);
cfg.zlim = ft_getopt(cfg, 'zlim', [-25 15]);
end
if isempty(cfg.dewar)
[v, p] = ft_version;
if isctf
cfg.dewar = fullfile(p, 'template', 'dewar', 'ctf.mat');
elseif isneuromag
cfg.dewar = fullfile(p, 'template', 'dewar', 'elekta.mat');
end
end
if ischar(cfg.dewar) && exist(cfg.dewar, 'file')
fprintf('reading dewar from file %s\n', cfg.dewar);
cfg.dewar = ft_read_headshape(cfg.dewar);
end
if ischar(cfg.headshape) && exist(cfg.headshape, 'file')
fprintf('reading headshape from file %s\n', cfg.headshape);
cfg.headshape = ft_read_headshape(cfg.headshape);
end
if ischar(cfg.polhemus) && exist(cfg.polhemus, 'file')
fprintf('reading polhemus data from file %s\n', cfg.polhemus);
cfg.polhemus = ft_read_headshape(cfg.polhemus);
elseif isneuromag
fprintf('reading polhemus data from file %s\n', cfg.dataset);
% Neuromag/Elekta/Megin dataset will contain head shape
cfg.polhemus = ft_read_headshape(cfg.dataset);
elseif isctf
fprintf('reading polhemus data from file %s\n', cfg.dataset);
% CTF dataset may contain electrode information
elec = ft_read_sens(cfg.dataset, 'senstype', 'eeg');
cfg.polhemus.pos = elec.elecpos;
cfg.polhemus.unit = elec.unit;
end
if ~isempty(cfg.headshape)
cfg.headshape = ft_convert_units(cfg.headshape, 'cm');
end
if ~isempty(cfg.polhemus)
cfg.polhemus = ft_convert_units(cfg.polhemus, 'cm');
end
if ~isempty(cfg.dewar)
cfg.dewar = ft_convert_units(cfg.dewar, 'cm');
end
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
% read template head position, to reposition to, if template file is specified
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
if isctf
if ~isempty(cfg.template)
[p, f, x] = fileparts(cfg.template);
if strcmp(x, '.ds')
shape = ft_read_headshape(cfg.template, 'coordsys', 'dewar', 'format', 'ctf_ds');
template(1,:) = [shape.fid.pos(1,1), shape.fid.pos(1,2), shape.fid.pos(1,3)]; % chan X pos
template(2,:) = [shape.fid.pos(2,1), shape.fid.pos(2,2), shape.fid.pos(2,3)];
template(3,:) = [shape.fid.pos(3,1), shape.fid.pos(3,2), shape.fid.pos(3,3)];
elseif strcmp(x, '.txt')
template = dlmread(cfg.template);
else
ft_error('incorrect template file specified');
end
else
template = [];
end
% remove CTF REF sensors, for plotting purposes
chansel = match_str(hdr.grad.chantype, 'meggrad');
hdr.grad.chanpos = hdr.grad.chanpos(chansel,:);
hdr.grad.chanori = hdr.grad.chanori(chansel,:);
hdr.grad.chantype = hdr.grad.chantype(chansel,:);
hdr.grad.label = hdr.grad.label(chansel,:);
hdr.grad.tra = hdr.grad.tra(chansel,:);
elseif isneuromag
if ~isempty(cfg.template)
[p, f, x] = fileparts(cfg.template);
if strcmp(x, '.fif')
shape = ft_read_headshape(cfg.template, 'coordsys', 'dewar', 'format', 'neuromag_fif');
template(1,:) = [shape.fid.pos(1,1), shape.fid.pos(1,2), shape.fid.pos(1,3)]; % chan X pos
template(2,:) = [shape.fid.pos(2,1), shape.fid.pos(2,2), shape.fid.pos(2,3)];
template(3,:) = [shape.fid.pos(3,1), shape.fid.pos(3,2), shape.fid.pos(3,3)];
elseif strcmp(x, '.txt')
template = dlmread(cfg.template);
end
else
template = [];
end
else
ft_error('the data does not resemble ctf, nor neuromag')
end % if ctf or neuromag
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
% read digitized head position (for dipole fitting)
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
if isctf
sens = hdr.grad;
% not needed for CTF275 systems
dip = [];
vol = [];
coilsignal = [];
elseif isneuromag
shape = ft_read_headshape(cfg.headerfile, 'coordsys', 'dewar', 'format', 'neuromag_fif', 'unit', 'cm');
for i = 1:min(size(shape.pos,1),length(cfg.coilfreq)) % for as many digitized or specified coils
if ~isempty(strfind(shape.label{i}, 'hpi'))
dip(i).pos = shape.pos(i,:); % chan X pos, initial guess for each of the dipole/coil positions
dip(i).mom = [0 0 0]';
end
end
if ~exist('dip', 'var')
ft_error('head localization requires digitized positions for Neuromag systems')
end
% prepare the forward model and the sensor array for subsequent fitting
% note that the forward model is a magnetic dipole in an infinite vacuum
cfg.channel = ft_channelselection('MEGMAG', hdr.label); % old
[vol, sens] = ft_prepare_vol_sens([], hdr.grad, 'channel', cfg.channel);
sens = ft_datatype_sens(sens, 'scaling', 'amplitude/distance', 'distance', 'cm'); % ensure SI units
coilsignal = [];
% update distances, given that sensor units are m an not cm
cfg.accuracy_green = cfg.accuracy_green/100;
cfg.accuracy_orange = cfg.accuracy_orange/100;
else
ft_error('the data does not resemble ctf, nor neuromag')
end % if ctf or neuromag
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
% define a subset of channels for reading
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
if isctf
[dum, chanindx] = match_str('headloc', hdr.chantype);
elseif isneuromag
% depending on wether movement compensation was done or only head position
% estimation, the fif file that results from Maxfilter will contain 9 channels that
% start with QUAT or with CHPI
if ~isempty(cfg.headmovement)
% load the head position information from cfg.headmovement
tmpcfg = [];
tmpcfg.dataset = cfg.headmovement;
tmpcfg.channel = 'QUAT*';
data_movement = ft_preprocessing(tmpcfg);
% ensure that it is regularly sampled
tmpcfg = [];
tmpcfg.time{1} = (1:data_movement.hdr.nSamples)/data_movement.hdr.Fs;
data_movement = ft_resampledata(tmpcfg, data_movement);
elseif sum(startsWith(hdr.label, 'QUAT'))==9
% the data only contains the estimated position, but has not been movement corrected
chanindx = find(startsWith(hdr.label, 'QUAT'));
elseif sum(startsWith(hdr.label, 'CHPI'))==9
% this is movement corrected data
chanindx = find(startsWith(hdr.label, 'CHPI'));
else
% select the 102 magnetometers for fitting of the HPI coils
[dum, chanindx] = match_str('megmag', hdr.chantype);
end
end
if isempty(chanindx)
ft_error('the data does not seem to have head localization channels');
end
% this information is passed between the GUI callback functions
info = [];
info.hdr = hdr;
info.blocksize = blocksize;
info.isctf = isctf;
info.isneuromag = isneuromag;
info.cfg = cfg;
info.template = template;
info.sens = sens;
info.vol = vol;
info.dip = dip;
info.continue = true;
clear hdr blocksize isctf isneuromag cfg template sens vol dip
% initiate main figure
hMainFig = figure;
% attach the info in the figure
guidata(hMainFig, info);
% initiate gui controls
uicontrol_sub(hMainFig);
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
% this is the general BCI loop where realtime incoming data is handled
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
while ishandle(hMainFig) && info.continue % while the flag is one, the loop continues
% get the potentially updated information from the main window
info = guidata(hMainFig);
% determine number of samples available in buffer
info.hdr = ft_read_header(info.cfg.headerfile, 'cache', true, 'coordsys', 'dewar');
% see whether new samples are available
newsamples = (info.hdr.nSamples*info.hdr.nTrials-prevSample);
if newsamples>=info.blocksize
if strcmp(info.cfg.bufferdata, 'last')
begsample = info.hdr.nSamples*info.hdr.nTrials - info.blocksize + 1;
endsample = info.hdr.nSamples*info.hdr.nTrials;
elseif strcmp(info.cfg.bufferdata, 'first')
begsample = prevSample + 1;
endsample = prevSample + info.blocksize;
else
ft_error('unsupported value for cfg.bufferdata');
end
% remember up to where the data was read
prevSample = endsample;
count = count + 1;
fprintf('processing segment %d from sample %d to %d\n', count, begsample, endsample);
% read data segment from buffer
dat = ft_read_data(info.cfg.datafile, 'header', info.hdr, 'begsample', begsample, 'endsample', endsample, 'chanindx', chanindx, 'checkboundary', false);
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
% from here onward it is specific to the head localization
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
% put the data in a fieldtrip-like raw structure
data.trial{1} = double(dat);
data.time{1} = offset2time(begsample, info.hdr.Fs, endsample-begsample+1);
data.label = info.hdr.label(chanindx);
data.hdr = info.hdr;
data.fsample = info.hdr.Fs;
if ~isempty(info.cfg.headmovement) && info.isneuromag
if ~all(startsWith(data.label, 'QUAT')) || ~all(startsWith(data.label, 'CHPI'))
data.trial{1} = data_movement.trial{1}(1:size(data_movement.trial{1}),begsample:endsample);
data.label = data_movement.label;
else
fprintf('Channels for head localisation already in the .fif file, will use data form the .fif file')
end
end
if info.isneuromag && size(coilsignal,2)~=info.blocksize
% construct the reference signal for each of the coils
% this needs to be updated if the blocksize changes
ncoil = length(info.cfg.coilfreq);
if ncoil==0
ft_error('no coil frequencies were specified');
else
time = (1:info.blocksize)./info.hdr.Fs;
coilsignal = zeros(ncoil, info.blocksize);
for i=1:ncoil
coilsignal(i,:) = exp(time*info.cfg.coilfreq(i)*1i*2*pi);
coilsignal(i,:) = coilsignal(i,:) / norm(coilsignal(i,:));
end
end
end
% compute the HPI coil positions, this takes some time
[hpi, info.dip] = data2hpi(data, info.dip, info.vol, info.sens, coilsignal, info.isctf, info.isneuromag); % for neuromag datasets this is relatively slow
guidata(hMainFig, info);
if ~ishandle(hMainFig)
% the figure has been closed
break
end
% get the potentially updated information from the main window
info = guidata(hMainFig);
% update the info
info.hpi = hpi;
% store the updated gui variables
guidata(hMainFig, info);
% DRAW LEFT PANEL - TOP VIEW
a = subplot(1,2,1);
h = get(a, 'children');
hold on;
if ~isempty(h)
% done on every iteration
delete(h);
end
% draw the color-coded head and distances from the templates
draw_sub(hMainFig);
% show current timesample
title(sprintf('top view, runtime = %d s\n', round(mean(data.time{1}))));
% not needed any more
clear data;
% viewing angle
if info.isctf
view(-45, 90)
elseif info.isneuromag
view(0, 90)
end
% DRAW RIGHT PANEL - FRONT/REAR VIEW
b = subplot(1,2,2);
i = get(b, 'children');
hold on;
if ~isempty(i)
% done on every iteration
delete(i);
end
% draw the color-coded head and distances from the templates
draw_sub(hMainFig);
% viewing angle
if get(info.hViewMirrorButton, 'Value') == 1
if info.isctf
set(gca, 'Ydir', 'reverse')
view(45, 0)
elseif info.isneuromag
set(gca, 'Ydir', 'reverse')
view(0, 0)
end
title(sprintf('Mirror view, clock time %s', datestr(now))); % show current data & time
else
if info.isctf
set(gca, 'Ydir', 'normal')
view(135, 0)
elseif info.isneuromag
set(gca, 'Ydir', 'normal')
view(180, 0)
end
title(sprintf('Normal view, clock time %s', datestr(now))); % show current data & time
end
% force Matlab to update the figure
drawnow
end % if enough new samples
end % while true
close(hMainFig); % close the figure
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
% SUBFUNCTION that initiates the figure
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
function uicontrol_sub(handle, eventdata)
% get the info
info = guidata(handle);
% initiate figure
set(handle, 'KeyPressFcn', {@key_sub});
hUpdateButton = uicontrol(...
'Parent', handle,...
'Style', 'pushbutton',...
'String', 'Update',...
'Units', 'normalized',...
'Position', [.65 .0875 .15 .075],...
'FontSize', 12,...
'Callback', {@update_ButtonDownFcn});
hQuitButton = uicontrol(...
'Parent', handle,...
'Style', 'pushbutton',...
'String', 'Quit',...
'Units', 'normalized',...
'Position', [.8 .0875 .15 .075],...
'FontSize', 12,...
'Callback', {@quit_ButtonDownFcn});
hSphereCheckBox = uicontrol(...
'Parent', handle,...
'Style', 'checkbox',...
'String', 'Sphere',...
'Units', 'normalized',...
'Position', [.05 .1 .075 .05],...
'FontSize', 8,...
'BackgroundColor', [.8 .8 .8],...
'Value', 1,...
'Callback', {@sphere_CheckBox});
hHeadCheckBox = uicontrol(...
'Parent', handle,...
'Style', 'checkbox',...
'String', 'Head',...
'Units', 'normalized',...
'Position', [.125 .1 .1 .05],...
'FontSize', 8,...
'BackgroundColor', [.8 .8 .8],...
'Value', 0,... % by default switched on
'Callback', {@head_CheckBox});
hPolhemusCheckBox = uicontrol(...
'Parent', handle,...
'Style', 'checkbox',...
'String', 'Polhemus',...
'Units', 'normalized',...
'Position', [.2 .1 .075 .05],...
'FontSize', 8,...
'BackgroundColor', [.8 .8 .8],...
'Value', 0,...
'Callback', {@Polhemus_CheckBox});
hDewarCheckBox = uicontrol(...
'Parent', handle,...
'Style', 'checkbox',...
'String', 'Dewar',...
'Units', 'normalized',...
'Position', [.275 .1 .075 .05],...
'FontSize', 8,...
'BackgroundColor', [.8 .8 .8],...
'Value', 0,...
'Callback', {@Dewar_CheckBox});
hCoilCheckBox = uicontrol(...
'Parent', handle,...
'Style', 'checkbox',...
'String', 'Coils',...
'Units', 'normalized',...
'Position', [.35 .1 .075 .05],...
'FontSize', 8,...
'BackgroundColor', [.8 .8 .8],...
'Value', 1,...
'Callback', {@coil_CheckBox});
hSensorCheckBox = uicontrol(...
'Parent', handle,...
'Style', 'checkbox',...
'String', 'Sensors',...
'Units', 'normalized',...
'Position', [.425 .1 .075 .05],...
'FontSize', 8,...
'BackgroundColor', [.8 .8 .8],...
'Value', 0,...
'Callback', {@sensor_CheckBox});
hAxisCheckBox = uicontrol(...
'Parent', handle,...
'Style', 'checkbox',...
'String', 'Axis',...
'Units', 'normalized',...
'Position', [.5 .1 .075 .05],...
'FontSize', 8,...
'BackgroundColor', [.8 .8 .8],...
'Value', 0,...
'Callback', {@axis_CheckBox});
hBlocksizeMenu = uicontrol(...
'Parent', handle,...
'Style', 'popupmenu',...
'String', {'.1 second', '.2 second', '.5 second', '1 second', '1.5 second', '2 seconds', '5 seconds', '10 seconds', '30 seconds'},...
'Units', 'normalized',...
'Position', [.6 .1925 .1 .05],...
'FontSize', 8,...
'BackgroundColor', [.8 .8 .8],...
'Value', 1,... % default
'Callback', {@blocksize_Menu});
hViewMirrorButton = uicontrol(...
'Parent', handle,...
'Style', 'checkbox',...
'String', 'Mirror View',...
'Units', 'normalized',...
'Position', [.8 .1925 .1 .05],...
'FontSize', 8,...
'BackgroundColor', [.8 .8 .8],...
'Value', 1,... % by default switched on
'Callback', {@mirror_CheckBox});
info.hQuitButton = hQuitButton;
info.hCoilCheckBox = hCoilCheckBox;
info.hSphereCheckBox = hSphereCheckBox;
info.hDewarCheckBox = hDewarCheckBox;
info.hSensorCheckBox = hSensorCheckBox;
info.hViewMirrorButton = hViewMirrorButton;
info.hBlocksizeMenu = hBlocksizeMenu;
info.hRealistic = hHeadCheckBox;
info.hPolhemusCheckBox = hPolhemusCheckBox;
info.hAxisCheckBox = hAxisCheckBox;
% put the info back
guidata(handle, info);
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
% SUBFUNCTION that computes the HPI coil positions
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
function [hpi, dip] = data2hpi(data, dip, vol, sens, coilsignal, isctf, isneuromag)
% The CTF275 system localizes the HPI coil positions online, and writes them
% to the dataset. For the Neuromag systems the signals evoked by the HPI coils
% are superimposed on the other signals. This requires additional online
% dipolefitting of those HPI coils.
if isctf
% assign the channels to the resp. coil coordinates
[dum, x1] = match_str('HLC0011', data.label);
[dum, y1] = match_str('HLC0012', data.label);
[dum, z1] = match_str('HLC0013', data.label);
[dum, x2] = match_str('HLC0021', data.label);
[dum, y2] = match_str('HLC0022', data.label);
[dum, z2] = match_str('HLC0023', data.label);
[dum, x3] = match_str('HLC0031', data.label);
[dum, y3] = match_str('HLC0032', data.label);
[dum, z3] = match_str('HLC0033', data.label);
% convert from meter to cm and assign to the resp. coil
hpi{1} = data.trial{1}([x1 y1 z1],end) * 100;
hpi{2} = data.trial{1}([x2 y2 z2],end) * 100;
hpi{3} = data.trial{1}([x3 y3 z3],end) * 100;
elseif isneuromag
if all(startsWith(data.label, 'QUAT'))
q1 = data.trial{1}(strcmp(data.label, 'QUAT001'),:);
q2 = data.trial{1}(strcmp(data.label, 'QUAT002'),:);
q3 = data.trial{1}(strcmp(data.label, 'QUAT003'),:);
q4 = -data.trial{1}(strcmp(data.label, 'QUAT004'),:);
q5 = -data.trial{1}(strcmp(data.label, 'QUAT005'),:);
q6 = -data.trial{1}(strcmp(data.label, 'QUAT006'),:);
q = [q1(1) q2(1) q3(1) q4(1) q5(1) q6(1)];
% compute the anatomical landmark location in cm
hpi{1} = ft_warp_apply(q(end,:), data.hdr.orig.dig(1).r' , 'quaternion')'*100;
hpi{2} = ft_warp_apply(q(end,:), data.hdr.orig.dig(2).r' , 'quaternion')'*100;
hpi{3} = ft_warp_apply(q(end,:), data.hdr.orig.dig(3).r' , 'quaternion')'*100;
elseif all(startsWith(data.label, 'CHPI'))
q1 = data.trial{1}(strcmp(data.label, 'CHPI001'),:);
q2 = data.trial{1}(strcmp(data.label, 'CHPI002'),:);
q3 = data.trial{1}(strcmp(data.label, 'CHPI003'),:);
q4 = -data.trial{1}(strcmp(data.label, 'CHPI004'),:);
q5 = -data.trial{1}(strcmp(data.label, 'CHPI005'),:);
q6 = -data.trial{1}(strcmp(data.label, 'CHPI006'),:);
q = [q1(1) q2(1) q3(1) q4(1) q5(1) q6(1)];
% compute the anatomical landmark location in cm
hpi{1} = ft_warp_apply(q(end,:), data.hdr.orig.dig(1).r' , 'quaternion')'*100;
hpi{2} = ft_warp_apply(q(end,:), data.hdr.orig.dig(2).r' , 'quaternion')'*100;
hpi{3} = ft_warp_apply(q(end,:), data.hdr.orig.dig(3).r' , 'quaternion')'*100;
else
% estimate the complex-valued MEG topography for each coil
% this implements a discrete Fourier transform (DFT)
topo = [];
%[x, ut] = svdfft( data.trial{1} );
%data.trial{1} = x;
topo = ft_preproc_detrend(data.trial{1}) * ctranspose(coilsignal);
% ignore the out-of-phase spectral component in the topography
topo = real(topo); % THIS SEEMS TO BE CRUCIAL
% fit a magnetic dipole to each of the topographies
constr.sequential = true; % for BTI systems this would be 'false' as all coils have the same frequency
constr.rigidbody = true;
% fit the coils together
dipall = [];
ncoil = numel(dip);
for i=1:ncoil
dipall.pos(i,:) = dip(i).pos;
end
dipall = ft_inverse_dipolefit(dipall, sens, vol, topo, 'constr', constr, 'display', 'off');
for i=1:ncoil
sel = (1:3) + 3*(i-1);
dip(i).pos = dipall.pos(i,:);
dip(i).mom = real(dipall.mom(sel,i)); % ignore the complex phase information
hpi{i} = dip(i).pos;
end
end
else
ft_error('the data does not resemble ctf, nor neuromag')
end % if ctf or neuromag
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
% SUBFUNCTION that does the timing
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
function [time] = offset2time(offset, fsample, nsamples)
offset = double(offset);
nsamples = double(nsamples);
time = (offset + (0:(nsamples-1)))/fsample;
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
% SUBFUNCTION which computes the circumcenter(x,y,z) of the 3D triangle (3 coils)
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
function [cc] = circumcenter(hpi)
% use coordinates relative to point `a' of the triangle
xba = hpi{2}(1) - hpi{1}(1);
yba = hpi{2}(2) - hpi{1}(2);
zba = hpi{2}(3) - hpi{1}(3);
xca = hpi{3}(1) - hpi{1}(1);
yca = hpi{3}(2) - hpi{1}(2);
zca = hpi{3}(3) - hpi{1}(3);
% squares of lengths of the edges incident to `a'
balength = xba * xba + yba * yba + zba * zba;
calength = xca * xca + yca * yca + zca * zca;
% cross product of these edges
xcrossbc = yba * zca - yca * zba;
ycrossbc = zba * xca - zca * xba;
zcrossbc = xba * yca - xca * yba;
% calculate the denominator of the formulae
denominator = 0.5 / (xcrossbc * xcrossbc + ycrossbc * ycrossbc + zcrossbc * zcrossbc);
% calculate offset (from `a') of circumcenter
xcirca = ((balength * yca - calength * yba) * zcrossbc - (balength * zca - calength * zba) * ycrossbc) * denominator;
ycirca = ((balength * zca - calength * zba) * xcrossbc - (balength * xca - calength * xba) * zcrossbc) * denominator;
zcirca = ((balength * xca - calength * xba) * ycrossbc - (balength * yca - calength * yba) * xcrossbc) * denominator;
cc(1) = xcirca + hpi{1}(1);
cc(2) = ycirca + hpi{1}(2);
cc(3) = zcirca + hpi{1}(3);
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
% SUBFUNCTION which draws the color-coded head and distances to the template
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
function draw_sub(handle)
% get the info
info = guidata(handle);
% compute transformation
if info.isctf
M = ft_headcoordinates([info.hpi{1}(1),info.hpi{1}(2),info.hpi{1}(3)], [info.hpi{2}(1),info.hpi{2}(2),info.hpi{2}(3)], [info.hpi{3}(1),info.hpi{3}(2),info.hpi{3}(3)], 'ctf');
elseif info.isneuromag
M = ft_headcoordinates([info.hpi{2}(1),info.hpi{2}(2),info.hpi{2}(3)], [info.hpi{1}(1),info.hpi{1}(2),info.hpi{1}(3)], [info.hpi{3}(1),info.hpi{3}(2),info.hpi{3}(3)], 'neuromag');
end
M(1:3,1:3) = inv(M(1:3,1:3));
M(1:3,4) = (-M(1:3,4)'/M(1:3,1:3))';
% plot the HPI mismatch
if get(info.hCoilCheckBox, 'Value')
if info.isctf
% draw nasion position
if ~isempty(info.template)
if abs(info.template(1,1))-info.cfg.accuracy_green < abs(info.hpi{1}(1)) && abs(info.hpi{1}(1)) < abs(info.template(1,1))+info.cfg.accuracy_green ...
&& abs(info.template(1,2))-info.cfg.accuracy_green < abs(info.hpi{1}(2)) && abs(info.hpi{1}(2)) < abs(info.template(1,2))+info.cfg.accuracy_green ...
&& abs(info.template(1,3))-info.cfg.accuracy_green < abs(info.hpi{1}(3)) && abs(info.hpi{1}(3)) < abs(info.template(1,3))+info.cfg.accuracy_green
plot3(info.hpi{1}(1),info.hpi{1}(2),info.hpi{1}(3), 'g^', 'MarkerFaceColor', [.5 1 .5], 'MarkerSize',25)
head1 = true;
elseif abs(info.template(1,1))-info.cfg.accuracy_orange < abs(info.hpi{1}(1)) && abs(info.hpi{1}(1)) < abs(info.template(1,1))+info.cfg.accuracy_orange ...
&& abs(info.template(1,2))-info.cfg.accuracy_orange < abs(info.hpi{1}(2)) && abs(info.hpi{1}(2)) < abs(info.template(1,2))+info.cfg.accuracy_orange ...
&& abs(info.template(1,3))-info.cfg.accuracy_orange < abs(info.hpi{1}(3)) && abs(info.hpi{1}(3)) < abs(info.template(1,3))+info.cfg.accuracy_orange
plot3(info.hpi{1}(1),info.hpi{1}(2),info.hpi{1}(3), 'y^', 'MarkerFaceColor', [1 .5 0], 'MarkerEdgeColor', [1 .5 0], 'MarkerSize', 25)
head1 = false;
else % when not in correct position
plot3(info.hpi{1}(1),info.hpi{1}(2), info.hpi{1}(3), 'r^', 'MarkerFaceColor', [1 0 0], 'MarkerSize', 25)
head1 = false;
end
else
plot3(info.hpi{1}(1),info.hpi{1}(2), info.hpi{1}(3), 'r^', 'MarkerFaceColor', [1 0 0], 'MarkerSize', 25)
head1 = false;
end
% draw left ear position
if ~isempty(info.template)
if abs(info.template(2,1))-info.cfg.accuracy_green < abs(info.hpi{2}(1)) && abs(info.hpi{2}(1)) < abs(info.template(2,1))+info.cfg.accuracy_green ...
&& abs(info.template(2,2))-info.cfg.accuracy_green < abs(info.hpi{2}(2)) && abs(info.hpi{2}(2)) < abs(info.template(2,2))+info.cfg.accuracy_green ...
&& abs(info.template(2,3))-info.cfg.accuracy_green < abs(info.hpi{2}(3)) && abs(info.hpi{2}(3)) < abs(info.template(2,3))+info.cfg.accuracy_green
plot3(info.hpi{2}(1),info.hpi{2}(2),info.hpi{2}(3), 'go', 'MarkerFaceColor', [.5 1 .5], 'MarkerSize',25)
head2 = true;
elseif abs(info.template(2,1))-info.cfg.accuracy_orange < abs(info.hpi{2}(1)) && abs(info.hpi{2}(1)) < abs(info.template(2,1))+info.cfg.accuracy_orange ...
&& abs(info.template(2,2))-info.cfg.accuracy_orange < abs(info.hpi{2}(2)) && abs(info.hpi{2}(2)) < abs(info.template(2,2))+info.cfg.accuracy_orange ...
&& abs(info.template(2,3))-info.cfg.accuracy_orange < abs(info.hpi{2}(3)) && abs(info.hpi{2}(3)) < abs(info.template(2,3))+info.cfg.accuracy_orange
plot3(info.hpi{2}(1),info.hpi{2}(2),info.hpi{2}(3), 'yo', 'MarkerFaceColor', [1 .5 0], 'MarkerEdgeColor', [1 .5 0], 'MarkerSize',25)
head2 = false;
else % when not in correct position
plot3(info.hpi{2}(1),info.hpi{2}(2), info.hpi{2}(3), 'ro', 'MarkerFaceColor', [1 0 0], 'MarkerSize', 25)
head2 = false;
end
else
plot3(info.hpi{2}(1),info.hpi{2}(2), info.hpi{2}(3), 'ro', 'MarkerFaceColor', [1 0 0], 'MarkerSize', 25)
head2 = false;
end
% draw right ear position
if ~isempty(info.template)
if abs(info.template(3,1))-info.cfg.accuracy_green < abs(info.hpi{3}(1)) && abs(info.hpi{3}(1)) < abs(info.template(3,1))+info.cfg.accuracy_green ...
&& abs(info.template(3,2))-info.cfg.accuracy_green < abs(info.hpi{3}(2)) && abs(info.hpi{3}(2)) < abs(info.template(3,2))+info.cfg.accuracy_green ...
&& abs(info.template(3,3))-info.cfg.accuracy_green < abs(info.hpi{3}(3)) && abs(info.hpi{3}(3)) < abs(info.template(3,3))+info.cfg.accuracy_green
plot3(info.hpi{3}(1),info.hpi{3}(2),info.hpi{3}(3), 'go', 'MarkerFaceColor', [.5 1 .5], 'MarkerSize',25)
head3 = true;
elseif abs(info.template(3,1))-info.cfg.accuracy_orange < abs(info.hpi{3}(1)) && abs(info.hpi{3}(1)) < abs(info.template(3,1))+info.cfg.accuracy_orange ...
&& abs(info.template(3,2))-info.cfg.accuracy_orange < abs(info.hpi{3}(2)) && abs(info.hpi{3}(2)) < abs(info.template(3,2))+info.cfg.accuracy_orange ...
&& abs(info.template(3,3))-info.cfg.accuracy_orange < abs(info.hpi{3}(3)) && abs(info.hpi{3}(3)) < abs(info.template(3,3))+info.cfg.accuracy_orange
plot3(info.hpi{3}(1),info.hpi{3}(2),info.hpi{3}(3), 'yo', 'MarkerFaceColor', [1 .5 0], 'MarkerEdgeColor', [1 .5 0], 'MarkerSize',25)
head3 = false;
else % when not in correct position
plot3(info.hpi{3}(1),info.hpi{3}(2), info.hpi{3}(3), 'ro', 'MarkerFaceColor', [1 0 0], 'MarkerSize', 25)
head3 = false;
end
else
plot3(info.hpi{3}(1),info.hpi{3}(2), info.hpi{3}(3), 'ro', 'MarkerFaceColor', [1 0 0], 'MarkerSize', 25)
head3 = false;
end
elseif info.isneuromag
% draw nasion position
if ~isempty(info.template)
if abs(info.template(1,1))-info.cfg.accuracy_green < abs(info.hpi{1}(1)) && abs(info.hpi{1}(1)) < abs(info.template(1,1))+info.cfg.accuracy_green ...
&& abs(info.template(1,2))-info.cfg.accuracy_green < abs(info.hpi{1}(2)) && abs(info.hpi{1}(2)) < abs(info.template(1,2))+info.cfg.accuracy_green ...
&& abs(info.template(1,3))-info.cfg.accuracy_green < abs(info.hpi{1}(3)) && abs(info.hpi{1}(3)) < abs(info.template(1,3))+info.cfg.accuracy_green
plot3(info.hpi{1}(1),info.hpi{1}(2),info.hpi{1}(3), 'go', 'MarkerFaceColor', [.5 1 .5], 'MarkerSize',25)
head1 = true;
elseif abs(info.template(1,1))-info.cfg.accuracy_orange < abs(info.hpi{1}(1)) && abs(info.hpi{1}(1)) < abs(info.template(1,1))+info.cfg.accuracy_orange ...
&& abs(info.template(1,2))-info.cfg.accuracy_orange < abs(info.hpi{1}(2)) && abs(info.hpi{1}(2)) < abs(info.template(1,2))+info.cfg.accuracy_orange ...
&& abs(info.template(1,3))-info.cfg.accuracy_orange < abs(info.hpi{1}(3)) && abs(info.hpi{1}(3)) < abs(info.template(1,3))+info.cfg.accuracy_orange
plot3(info.hpi{1}(1),info.hpi{1}(2),info.hpi{1}(3), 'yo', 'MarkerFaceColor', [1 .5 0], 'MarkerEdgeColor', [1 .5 0], 'MarkerSize',25)
head1 = false;
else % when not in correct position
plot3(info.hpi{1}(1),info.hpi{1}(2), info.hpi{1}(3), 'ro', 'MarkerFaceColor', [1 0 0], 'MarkerSize', 25)
head1 = false;
end
else
plot3(info.hpi{1}(1),info.hpi{1}(2), info.hpi{1}(3), 'ro', 'MarkerFaceColor', [1 0 0], 'MarkerSize', 25)
head1 = false;
end
% draw left ear position
if ~isempty(info.template)
if abs(info.template(2,1))-info.cfg.accuracy_green < abs(info.hpi{2}(1)) && abs(info.hpi{2}(1)) < abs(info.template(2,1))+info.cfg.accuracy_green ...
&& abs(info.template(2,2))-info.cfg.accuracy_green < abs(info.hpi{2}(2)) && abs(info.hpi{2}(2)) < abs(info.template(2,2))+info.cfg.accuracy_green ...
&& abs(info.template(2,3))-info.cfg.accuracy_green < abs(info.hpi{2}(3)) && abs(info.hpi{2}(3)) < abs(info.template(2,3))+info.cfg.accuracy_green
plot3(info.hpi{2}(1),info.hpi{2}(2),info.hpi{2}(3), 'g^', 'MarkerFaceColor', [.5 1 .5], 'MarkerSize', 25)
head2 = true;
elseif abs(info.template(2,1))-info.cfg.accuracy_orange < abs(info.hpi{2}(1)) && abs(info.hpi{2}(1)) < abs(info.template(2,1))+info.cfg.accuracy_orange ...
&& abs(info.template(2,2))-info.cfg.accuracy_orange < abs(info.hpi{2}(2)) && abs(info.hpi{2}(2)) < abs(info.template(2,2))+info.cfg.accuracy_orange ...
&& abs(info.template(2,3))-info.cfg.accuracy_orange < abs(info.hpi{2}(3)) && abs(info.hpi{2}(3)) < abs(info.template(2,3))+info.cfg.accuracy_orange
plot3(info.hpi{2}(1),info.hpi{2}(2),info.hpi{2}(3), 'y^', 'MarkerFaceColor', [1 .5 0], 'MarkerEdgeColor', [1 .5 0], 'MarkerSize', 25)
head2 = false;
else % when not in correct position
plot3(info.hpi{2}(1),info.hpi{2}(2), info.hpi{2}(3), 'r^', 'MarkerFaceColor', [1 0 0], 'MarkerSize', 25)
head2 = false;
end
else
plot3(info.hpi{2}(1),info.hpi{2}(2), info.hpi{2}(3), 'r^', 'MarkerFaceColor', [1 0 0], 'MarkerSize', 25)
head2 = false;
end
% draw right ear position
if ~isempty(info.template)
if abs(info.template(3,1))-info.cfg.accuracy_green < abs(info.hpi{3}(1)) && abs(info.hpi{3}(1)) < abs(info.template(3,1))+info.cfg.accuracy_green ...
&& abs(info.template(3,2))-info.cfg.accuracy_green < abs(info.hpi{3}(2)) && abs(info.hpi{3}(2)) < abs(info.template(3,2))+info.cfg.accuracy_green ...
&& abs(info.template(3,3))-info.cfg.accuracy_green < abs(info.hpi{3}(3)) && abs(info.hpi{3}(3)) < abs(info.template(3,3))+info.cfg.accuracy_green
plot3(info.hpi{3}(1),info.hpi{3}(2),info.hpi{3}(3), 'go', 'MarkerFaceColor', [.5 1 .5], 'MarkerSize', 25)
head3 = true;
elseif abs(info.template(3,1))-info.cfg.accuracy_orange < abs(info.hpi{3}(1)) && abs(info.hpi{3}(1)) < abs(info.template(3,1))+info.cfg.accuracy_orange ...
&& abs(info.template(3,2))-info.cfg.accuracy_orange < abs(info.hpi{3}(2)) && abs(info.hpi{3}(2)) < abs(info.template(3,2))+info.cfg.accuracy_orange ...
&& abs(info.template(3,3))-info.cfg.accuracy_orange < abs(info.hpi{3}(3)) && abs(info.hpi{3}(3)) < abs(info.template(3,3))+info.cfg.accuracy_orange
plot3(info.hpi{3}(1),info.hpi{3}(2),info.hpi{3}(3), 'yo', 'MarkerFaceColor', [1 .5 0], 'MarkerEdgeColor', [1 .5 0], 'MarkerSize', 25)
head3 = false;
else % when not in correct position
plot3(info.hpi{3}(1),info.hpi{3}(2), info.hpi{3}(3), 'ro', 'MarkerFaceColor', [1 0 0], 'MarkerSize', 25)
head3 = false;
end
else
plot3(info.hpi{3}(1),info.hpi{3}(2), info.hpi{3}(3), 'ro', 'MarkerFaceColor', [1 0 0], 'MarkerSize', 25)
head3 = false;
end
end
end
% plot the template fiducial positions
if ~isempty(info.template)
if info.isctf
plot3(info.template(1,1), info.template(1,2), info.template(1,3), 'k^', 'MarkerSize', 27, 'LineWidth', 2); % chan X pos
plot3(info.template(2,1), info.template(2,2), info.template(2,3), 'ko', 'MarkerSize', 27, 'LineWidth', 2);
plot3(info.template(3,1), info.template(3,2), info.template(3,3), 'ko', 'MarkerSize', 27, 'LineWidth', 2);
text(-8,8, info.template(2,3), 'Left', 'FontSize', 15);
text(6,-6, info.template(3,3), 'Right', 'FontSize', 15);
elseif info.isneuromag
plot3(info.template(1,1), info.template(1,2), info.template(1,3), 'ko', 'MarkerSize', 27, 'LineWidth', 2); % chan X pos
plot3(info.template(2,1), info.template(2,2), info.template(2,3), 'k^', 'MarkerSize', 27, 'LineWidth', 2);
plot3(info.template(3,1), info.template(3,2), info.template(3,3), 'ko', 'MarkerSize', 27, 'LineWidth', 2);
end
end
% plot sphere model
if get(info.hSphereCheckBox, 'Value')
cc = circumcenter(info.hpi);
x_radius = sqrt((info.hpi{2}(1) - cc(1))^2 + (info.hpi{2}(2) - cc(2))^2);
y_radius = sqrt((info.hpi{3}(1) - cc(1))^2 + (info.hpi{3}(2) - cc(2))^2);
[xe, ye, ze] = ellipsoid(cc(1),cc(2),cc(3),x_radius,y_radius,11);
hh = surfl(xe, ye, ze);
shading interp
if get(info.hCoilCheckBox, 'Value') % this only works if 'coils' are updated
if head1 == true && head2 == true && head3 == true
colormap cool
else
colormap hot
end
end
alpha(.15)
end
% plot realistic head mdoel
if get(info.hRealistic, 'Value') && ~isempty(info.cfg.headshape)
ft_plot_mesh(ft_transform_geometry(M, info.cfg.headshape))
end
% plot sensors
if get(info.hSensorCheckBox, 'Value') && ~isempty(info.sens)
% plot the sensors
ft_plot_sens(info.hdr.grad, 'style', 'k.');
end
% plot the HPI coil positions
for j = 1:numel(info.hpi)
plot3(info.hpi{j}(1), info.hpi{j}(2), info.hpi{j}(3), 'ko', 'LineWidth', 1, 'MarkerSize', 5)
end
% plot the dewar
if get(info.hDewarCheckBox, 'Value') && ~isempty(info.cfg.dewar)
ft_plot_mesh(info.cfg.dewar, 'facecolor', [0.5 0.5 0.5], 'facealpha', 0.6, 'edgecolor', 'none');
end
% plot Polhemus
if get(info.hPolhemusCheckBox, 'Value')
if ~isempty(info.cfg.polhemus)
ft_plot_mesh(ft_transform_geometry(M,info.cfg.polhemus), 'vertexmarker', '.')
end
end
% plot Axis
if get(info.hAxisCheckBox, 'Value')
if info.isctf
ft_plot_axes([], 'coordsys', 'ctf', 'unit', 'cm');
elseif info.isneuromag
ft_plot_axes([], 'coordsys', 'neuromag', 'unit', 'cm');
end
end
grid on
axis on
xlabel('x (cm)');
ylabel('y (cm)');
zlabel('z (cm)');
% place ticks at 2cm distance
set(gca, 'xtick', info.cfg.xlim(1):2:info.cfg.xlim(2))
set(gca, 'ytick', info.cfg.ylim(1):2:info.cfg.ylim(2))
set(gca, 'ztick', info.cfg.zlim(1):2:info.cfg.zlim(2))
% fix axis to avoid rescaling
axis([info.cfg.xlim info.cfg.ylim info.cfg.zlim])
axis square
% put the info back
guidata(handle, info);
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
% SUBFUNCTION which handles hot keys in the current plot
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
function key_sub(handle, eventdata)
% get the info
info = guidata(handle);
switch eventdata.Key
case 'u'
% update the template positions
fprintf('updating template coordinates \n')
for j = 1:numel(info.hpi)
info.template(j,:) = info.hpi{j}(:); % chan X pos
end
% write template position to text file for later re-positioning
template_time = [date datestr(now, '-HH-MM-SS')];
fprintf('writing to %s.txt \n', template_time);
dlmwrite([template_time '.txt'], info.template, ' ');
case 'q'
% stop the application
fprintf('stopping the application \n')
info.continue = false;
case 'c'
% display the sensors/dewar
if get(info.hCoilCheckBox, 'Value') == 0
fprintf('displaying coils \n')
set(info.hCoilCheckBox, 'Value', 1); % toggle on
elseif get(info.hCoilCheckBox, 'Value') == 1
set(info.hCoilCheckBox, 'Value', 0); % toggle off
end
case 'h'
% display the sensors/dewar
if get(info.hHeadCheckBox, 'Value') == 0
fprintf('displaying head \n')
set(info.hHeadCheckBox, 'Value', 1); % toggle on
elseif get(info.hHeadCheckBox, 'Value') == 1
set(info.hHeadCheckBox, 'Value', 0); % toggle off
end
case 's'
% display the sensors/dewar
if get(info.hSensorCheckBox, 'Value') == 0
fprintf('displaying sensors/dewar \n')
set(info.hSensorCheckBox, 'Value', 1); % toggle on
elseif get(info.hSensorCheckBox, 'Value') == 1
set(info.hSensorCheckBox, 'Value', 0); % toggle off
end
otherwise
fprintf('no command executed \n')
end
% put the info back
guidata(handle, info);
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
% SUBFUNCTIONs which handle button presses
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
function update_ButtonDownFcn(handle, eventdata)
% get the info
info = guidata(handle);
% update the template positions
fprintf('updating template coordinates \n')
for j = 1:numel(info.hpi)
info.template(j,:) = info.hpi{j}(:); % chan X pos
end
% write template position to text file for later re-positioning
template_time = [date datestr(now, '-HH-MM-SS')];
fprintf('writing to %s.txt \n', template_time);
dlmwrite([template_time '.txt'], info.template, ' ');
% put the info back
guidata(handle, info);
function quit_ButtonDownFcn(handle, eventdata)
% get the info
info = guidata(handle);
% stop the application
fprintf('stopping the application \n')
info.continue = false;
% put the info back
guidata(handle, info);
function coil_CheckBox(hObject, eventdata)
% toggle coils display
function sphere_CheckBox(hObject, eventdata)
% toggle head display
function sensor_CheckBox(hObject, eventdata)
% toggle sensors display
function head_CheckBox(hObject, eventdata)
% toggle head display
function Dewar_CheckBox(hObject, eventdata)
% toggle dewar display
function axis_CheckBox(hObject, eventdata)
% toggle axis display
function Polhemus_CheckBox(hObject, eventdata)
% toggle axis display
function mirror_CheckBox(handle, eventdata)
% toggle mirror display
function blocksize_Menu(handle, eventdata)
% get the info
info = guidata(handle);
val = get(info.hBlocksizeMenu, 'Value');
switch val
case 1
info.blocksize = round(0.1 * info.hdr.Fs); % 0.1 s
case 2
info.blocksize = round(0.2 * info.hdr.Fs);
case 3
info.blocksize = round(0.5 * info.hdr.Fs);
case 4
info.blocksize = round(1 * info.hdr.Fs);
case 5
info.blocksize = round(1.5 * info.hdr.Fs);
case 6
info.blocksize = round(2 * info.hdr.Fs);
case 7
info.blocksize = round(5 * info.hdr.Fs);
case 8
info.blocksize = round(10 * info.hdr.Fs);
case 9
info.blocksize = round(30 * info.hdr.Fs);
end
fprintf('changing blocksize to %d samples\n', info.blocksize);
% put the info back
guidata(handle, info);