function EEG=FASTER_process(option_wrapper,log_file) % Copyright (C) 2010 Hugh Nolan, Robert Whelan and Richard Reilly, Trinity College Dublin, % Ireland % nolanhu@tcd.ie, robert.whelan@tcd.ie % % This program 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 2 of the License, or % (at your option) any later version. % % This program 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 this program; if not, write to the Free Software % Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA EEG=[]; try tic; o=option_wrapper.options; %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % File options % %%%%%%%%%%%%%%%% % 1 File name including full path (string) % 2 Reference channel (integer > 0) % 3 Number of data channels (integer > 0) % 4 Number of extra channels (integer > 0) % 5 Channel locations file including full path (string) % 6 Save options (cell) %%%%%%%%%%%%%%%% using_ALLEEG=o.file_options.using_ALLEEG; prefix=o.file_options.file_prefix; %prefix_ALLEEG=o.file_options.prefix_ALLEEG; fullfilename = o.file_options.current_file; ref_chan = o.channel_options.ref_chan; eeg_chans = o.channel_options.eeg_chans; if (eeg_chans==0) eeg_chans=[]; end ext_chans = o.channel_options.ext_chans; if (ext_chans==0) ext_chans=[]; end channel_locations_file = o.file_options.channel_locations; save_options = o.save_options; cutoff_markers = o.file_options.cutoff_markers; do_reref = o.channel_options.do_reref; if (~do_reref) ref_chan=[]; end [filepath,filename,extension] = fileparts(fullfilename); %log_file = fopen([filepath filesep filename '.log'],'a'); c=clock; months={'Jan' 'Feb' 'Mar' 'Apr' 'May' 'Jun' 'Jul' 'Aug' 'Sep' 'Oct' 'Nov' 'Dec'}; fprintf(log_file,'\n%d/%s/%d %d:%d:%d\n',c(3),months{c(2)},c(1),c(4),c(5),round(c(6))); fprintf(log_file,'%.2f - Opened log file.\n',toc); %%%%%%%%%%%%%%%%%%%%%% % File setup section % %%%%%%%%%%%%%%%%%%%%%% % Import .bdf file or load .set file % Note: import all channels and then remove the unnecessary ones, as % otherwise the event channel gets removed and we have no event data. if strcmpi(extension,'.bdf') && ~using_ALLEEG fprintf('Importing %s.\n',fullfilename); EEG = pop_biosig(fullfilename); EEG.setname = filename; EEG = pop_select(EEG, 'nochannel',length(eeg_chans)+length(ext_chans)+1:size(EEG.data,1)); if (do_reref) if (max(EEG.data(ref_chan,:))==0 && min(EEG.data(ref_chan,:))==0) fprintf(log_file,'%.2f - Reference channel %d is already zeroed. Data was not re-referenced.\n',toc,ref_chan); elseif (o.ica_options.keep_ICA && ~isempty(EEG.icaweights)) fprintf(log_file,'%.2f - Data was not re-referenced to maintain existing ICA weights. Bad channel detection may be ineffective.\n',toc,ref_chan); else EEG = h_pop_reref( EEG, ref_chan, 'exclude', ext_chans, 'keepref', 'on'); end end filename = [o.file_options.file_prefix filename]; filepath=o.file_options.oplist{o.file_options.current_file_num}; mkdir([filepath filesep 'Intermediate']); EEG = pop_saveset(EEG,'filename',[filename '.set'],'filepath',filepath,'savemode','onefile'); fprintf(log_file,'%.2f - Imported and converted file %s.\n',toc,fullfilename); elseif strcmpi(extension,'.set') && ~using_ALLEEG fprintf('Loading %s.\n',fullfilename); EEG = pop_loadset('filename',[filename '.set'],'filepath',filepath); fprintf(log_file,'%.2f - Loaded file %s.\n',toc,fullfilename); if ~isempty(o.file_options.output_folder_name) filepath=o.file_options.oplist{o.file_options.current_file_num}; mkdir([filepath filesep 'Intermediate']); else filepath=o.file_options.oplist{o.file_options.current_file_num}; mkdir([filepath filesep 'Intermediate']); pop_saveset(EEG,'filename',['Original_' filename '.set'],'filepath',[filepath filesep 'Intermediate']); delete(fullfilename); if exist([fullfilename(1:end-4) '.fdt'],'file') delete([fullfilename(1:end-4) '.fdt']); end if exist([fullfilename(1:end-4) '.dat'],'file') delete([fullfilename(1:end-4) '.dat']); end end filename = [o.file_options.file_prefix filename]; EEG.filename = [filename '.set']; elseif using_ALLEEG EEG=evalin('base',sprintf('ALLEEG(%d);',o.file_options.plist{o.file_options.current_file_num})); filepath=o.file_options.oplist{o.file_options.current_file_num}; if ~isempty(EEG.filename) filename=sprintf('%s%s.set',prefix,EEG.filename); elseif ~isempty(EEG.setname) filename=sprintf('%sALLEEG(%d)_%s.set',prefix,o.file_options.current_file_num,EEG.setname); else filename=sprintf('%sALLEEG(%d).set',prefix,o.file_options.current_file_num); end EEG.filepath=filepath; EEG.filename=filename; mkdir([filepath filesep 'Intermediate']); EEG = pop_select(EEG, 'nochannel',length(eeg_chans)+length(ext_chans)+1:size(EEG.data,1)); if (do_reref) if (max(EEG.data(ref_chan,:))==0 && min(EEG.data(ref_chan,:))==0) fprintf(log_file,'%.2f - Reference channel %d is already zeroed. Data was not re-referenced.\n',toc,ref_chan); elseif (o.ica_options.keep_ICA && ~isempty(EEG.icaweights)) fprintf(log_file,'%.2f - Data was not re-referenced to maintain existing ICA weights. Bad channel detection may be ineffective.\n',toc,ref_chan); else EEG = h_pop_reref( EEG, ref_chan, 'exclude', ext_chans, 'keepref', 'on'); end end else EEG=[]; fprintf('Unknown file format.\n'); fprintf(log_file,'%.2f - Unknown file format. Cannot process.\n',toc); return; end EEG = eeg_checkset(EEG); % Check if channel locations exist, and if not load them from disk. if (~isfield(EEG.chanlocs,'X') || ~isfield(EEG.chanlocs,'Y') || ~isfield(EEG.chanlocs,'Z') || isempty(EEG.chanlocs)) || isempty([EEG.chanlocs(:).X]) || isempty([EEG.chanlocs(:).Y]) || isempty([EEG.chanlocs(:).Z]) EEG = pop_chanedit(EEG, 'load', {channel_locations_file}); EEG.saved='no'; fprintf(log_file,'%.2f - Loaded channel locations file from %s.\n',toc,channel_locations_file); end %EEG = pop_saveset(EEG,'savemode','resave'); %%%%%%%%%%%%%%%% % Save options % %%%%%%%%%%%%%%%% do_saves=(~using_ALLEEG || (o.file_options.save_ALLEEG && ~isempty(EEG.filename)) || ~isempty(o.file_options.output_folder_name)); if (~do_saves) save_options = zeros(size(save_options)); else EEG = pop_saveset(EEG,'filename',[filename '.set'],'filepath',filepath,'savemode','onefile'); end save_before_filter = save_options(1); save_before_interp = save_options(2); save_before_epoch = save_options(3); save_before_ica_rej = save_options(4); save_before_epoch_interp = save_options(5); if save_before_filter EEGBAK=EEG; EEGBAK.setname = ['pre_filt_' EEG.setname]; pop_saveset(EEGBAK,'filename',['1_pre_filt_' EEG.filename],'filepath',[filepath filesep 'Intermediate'],'savemode','onefile'); clear EEGBAK; end %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % Filtering % %%%%%%%%%%%%% resample_frequency=o.filter_options.resample_freq; do_resample=o.filter_options.resample_on; % Downsampling is done later (shouldn't really be done at all). do_hipass=o.filter_options.hpf_on; do_lopass=o.filter_options.lpf_on; do_notch=o.filter_options.notch_on; if any(any(isnan(EEG.data))) fprintf('NaN in EEG data before filtering.\n'); end if do_hipass w_h=o.filter_options.hpf_freq; t_h=o.filter_options.hpf_bandwidth; r_h=o.filter_options.hpf_ripple; a_h=o.filter_options.hpf_attenuation; [m, wtpass, wtstop] = pop_firpmord([w_h-(t_h) w_h+(t_h)], [0 1], [10^(-1*abs(a_h)/20) (10^(r_h/20)-1)/(10^(r_h/20)+1)], EEG.srate); if mod(m,2);m=m+1;end; EEG = pop_firpm(EEG, 'fcutoff', w_h, 'ftrans', t_h, 'ftype', 'highpass', 'wtpass', wtpass, 'wtstop', wtstop, 'forder', m); EEG.saved='no'; fprintf(log_file,'%.2f - Highpass filter: %.3fHz, transition band: %.2f, order: %d.\n',toc,w_h,t_h,m); end if do_lopass w_l=o.filter_options.lpf_freq; t_l=o.filter_options.lpf_bandwidth; r_l=o.filter_options.lpf_ripple; a_l=o.filter_options.lpf_attenuation; [m, wtpass, wtstop] = pop_firpmord([w_l-(t_l) w_l+(t_l)], [1 0], [(10^(r_l/20)-1)/(10^(r_l/20)+1) 10^(-1*abs(a_l)/20)], EEG.srate); if mod(m,2);m=m+1;end; EEG = pop_firpm(EEG, 'fcutoff', w_l, 'ftrans', t_l, 'ftype', 'lowpass', 'wtpass', wtpass, 'wtstop', wtstop, 'forder', m); EEG.saved='no'; fprintf(log_file,'%.2f - Lowpass filter: %.3fHz, transition band: %.2f, order: %d.\n',toc,w_l,t_l,m); end if do_notch for n=1:length(o.filter_options.notch_freq) w_n=[o.filter_options.notch_freq(n)-o.filter_options.notch_bandwidth1/2 o.filter_options.notch_freq(n)+o.filter_options.notch_bandwidth1/2]; t_n=o.filter_options.notch_bandwidth2; r_n=o.filter_options.notch_ripple; a_n=o.filter_options.notch_attenuation; [m, wtpass, wtstop] = pop_firpmord([w_n(1)-(t_n) w_n(1)+(t_n) w_n(2)-(t_n) w_n(2)+(t_n)], [0 1 0], [10^(-1*abs(a_n)/20) (10^(r_n/20)-1)/(10^(r_n/20)+1) 10^(-1*abs(a_n)/20)], EEG.srate); if mod(m,2);m=m+1;end; EEG = pop_firpm(EEG, 'fcutoff', w_n, 'ftrans', t_n, 'ftype', 'bandstop', 'wtpass', wtpass, 'wtstop', wtstop, 'forder', m); EEG.saved='no'; fprintf(log_file,'%.2f - Notch filter: %.3f to %.3fHz, transition band: %.2f, order: %d.\n',toc,w_n(1),w_n(2),t_n,m); end end if (do_saves), EEG = pop_saveset(EEG,'savemode','resave'); end if save_before_interp EEGBAK=EEG; EEGBAK.setname = ['pre_interp_' EEG.setname]; pop_saveset(EEGBAK,'filename',['2_pre_interp_' EEG.filename],'filepath',[filepath filesep 'Intermediate'],'savemode','onefile'); clear EEGBAK; end %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % Data cutoff point % % Will be re-implemented % %%%%%%%%%%%%%%%%%%%%%%%%%% % if ~isempty(cutoff_markers) && any(cutoff_markers) % cutoff_point=[0 size(EEG.data,2)+1]; % for u=1:length(EEG.event) % if EEG.event(u).type == cutoff_markers(1) || strcmp(EEG.event(u).type,cutoff_markers(1)) % cutoff_point(1)=EEG.event(u).latency; % Finds the last 255 (check this one) % end % if EEG.event(u).type == cutoff_markers(2) || strcmp(EEG.event(u).type,cutoff_markers(2)) % cutoff_point(2)=EEG.event(u).latency; % Finds the last 255 (check this one) % end % end % if cutoff_point(1) > 1 % EEG = pop_select( EEG, 'nopoint',[1 cutoff_point(1)] ); % end % if cutoff_point(2) < size(EEG.data,2) % EEG = pop_select( EEG, 'nopoint',[cutoff_point(2) size(EEG.data(:,:),2)] ); % end % end % %New cutoff points for VESPA % % EEG = remevent(EEG,768);EEG=remevent(EEG,33536); % % % first_real_event = -1; % last_real_event = -1; % % for u=1:length(EEG.event)-2 % % if ((EEG.event(u).latency - EEG.event(u+1).latency) * (1000/EEG.srate) < 100 && (EEG.event(u+1).latency - EEG.event(u+2).latency) * (1000/EEG.srate) < 100 && first_real_event == -1) % first_real_event = u; % end % % if (first_real_event ~= -1 && (EEG.event(u).latency - EEG.event(u+1).latency) * (1000/EEG.srate) > 100 && (EEG.event(u+1).latency - EEG.event(u+2).latency) * (1000/EEG.srate) > 100 && last_real_event == -1) % last_real_event = u; % end % % end % % first_real_time=max(EEG.event(first_real_event).latency - EEG.srate,1); % % if (last_real_event==-1) % last_real_time=min(EEG.event(end).latency + EEG.srate,size(EEG.data(:,:),2)); % else % last_real_time=min(EEG.event(last_real_event).latency + EEG.srate,1); % end % % EEG = pop_select( EEG, 'point',[first_real_time:last_real_time] ); % EEG.saved='no'; % EEG = pop_saveset(EEG,'savemode','resave'); % % fprintf(log_file,'Cropped between %.2f and %.2f seconds.\n',first_real_time/EEG.srate,last_real_time/EEG.srate); %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % Channel interpolation options % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % 1 Automatic interpolation of bad channels on or off (1 / 0) % 2 Radius for channel interpolation hypersphere (integer > 0) % 3 Automatic interpolation of channels per single epoch at end of process (1 / 0) % 4 Radius for epoch interpolation hypersphere (integer > 0) %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% chans_to_interp=[]; do_auto_interp = o.channel_options.channel_rejection_on; if do_auto_interp list_properties = channel_properties(EEG,eeg_chans,ref_chan); lengths = min_z(list_properties,o.channel_options.rejection_options); % Need to edit to make rejection_options.measure a vector, instead of multiple fields chans_to_interp = union(eeg_chans(logical(lengths)),o.channel_options.bad_channels); chans_to_interp = setdiff(chans_to_interp,ref_chan); % Ref chan may appear bad, but we shouldn't interpolate it! if (o.channel_options.exclude_EOG_chans) chans_to_interp = setdiff(chans_to_interp,o.ica_options.EOG_channels); end if ~o.channel_options.interp_after_ica if ~isempty(chans_to_interp) fprintf('Interpolating channel(s)'); fprintf(' %d',chans_to_interp); fprintf('.\n'); EEG = h_eeg_interp_spl(EEG,chans_to_interp,ext_chans); EEG.saved='no'; fprintf(log_file,'%.2f - Interpolated channels',toc); fprintf(log_file,' %d',chans_to_interp); fprintf(log_file,'.\n'); end end end if (do_saves), EEG = pop_saveset(EEG,'savemode','resave'); end if save_before_epoch EEGBAK=EEG; EEGBAK.setname = ['pre_epoch_' EEG.setname]; pop_saveset(EEGBAK,'filename',['3_pre_epoch_' EEG.filename],'filepath',[filepath filesep 'Intermediate'],'savemode','onefile'); clear EEGBAK; end %%% Do resampling here (if done pre-filtering, it creates problems). %%% %%% It does anyway, it seems. %%% if do_resample old_name = EEG.setname; old_srate = EEG.srate; EEG = pop_resample( EEG, resample_frequency); EEG.setname = old_name; fprintf(log_file,'%.2f - Resampled from %dHz to %dHz.\n',toc,old_srate,resample_frequency); end %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % Epoch options % %%%%%%%%%%%%%%%%% % 1 Epoching on or off (1 / 0) % 2 Markers to epoch from (array of integers or cell of strings) % 3 Epoch length (vector of 2 floats, 1 negative, 1 positive) - seconds % 4 Baseline length for mean subtraction (vector of 2 integers) (0 => baseline subtraction off) - milliseconds % 5 Auto epoch rejection on or off (1 / 0) % 6 Radius for epoch rejection hypersphere (integer > 0) %%%%%%%%%%%%%%%%% markers = o.epoch_options.epoch_markers; epoch_length = o.epoch_options.epoch_limits; baseline_time = o.epoch_options.baseline_sub * 1000; do_epoch_rejection = o.epoch_options.epoch_rejection_on; do_epoching = ((~isempty(markers) && o.epoch_options.markered_epoch) || o.epoch_options.unmarkered_epoch) && any(o.epoch_options.epoch_limits) && length(o.epoch_options.epoch_limits)==2; %%%%%%%%%%%%%% % Epoch data % %%%%%%%%%%%%%% if do_epoching oldname = EEG.setname; if ~o.epoch_options.unmarkered_epoch EEGt = h_epoch(EEG,markers,epoch_length); EEG.setname = oldname; EEG.saved='no'; if isnumeric(markers) fprintf(log_file,'%.2f - Epoched data on markers',toc); fprintf(log_file,' %d',markers); fprintf(log_file,'.\n'); else fprintf(log_file,'%.2f - Epoched data on markers',toc); fprintf(log_file,' %s',markers{:}); fprintf(log_file,'.\n'); end if size(EEG.data,3)==0 fprintf(log_file,'Epoch length too short, no epochs were generated.\n'); else EEG=EEGt; clear EEGt; end else EEG = eeg_regepochs(EEG,o.epoch_options.unmarkered_epoch_interval,epoch_length,NaN); EEG.setname = oldname; EEG.saved='no'; fprintf(log_file,'%.2f - Epoched data every %.2f seconds.\n',toc,o.epoch_options.unmarkered_epoch_interval); end % Remove epoch baselines after epoching: if any(baseline_time) EEG = pop_rmbase( EEG, baseline_time); end end if (size(EEG.data,3)>1) % Rereference just to print baseline variance, as otherwise the initial % BL variance is with a single reference, and the final in average % reference EEGtemp = h_pop_reref(EEG, [], 'exclude',ext_chans, 'refstate', ref_chan); fprintf(log_file,'Initial baseline variance: %.2f.\n',median(var(mean(EEGtemp.data(:,1:round(EEGtemp.srate*-1*EEGtemp.xmin),:),3),[],2))); clear EEGtemp; end if (do_saves), EEG = pop_saveset(EEG,'savemode','resave'); end %%%%%%%%%%%%%%%%%%%%%%%%%%% % Epoch rejection section % %%%%%%%%%%%%%%%%%%%%%%%%%%% if do_epoch_rejection && size(EEG.data,3)>1 if (o.channel_options.interp_after_ica) list_properties = epoch_properties(EEG,setdiff(eeg_chans,chans_to_interp)); else list_properties = epoch_properties(EEG,eeg_chans); end [lengths] = min_z(list_properties,o.epoch_options.rejection_options); EEG=pop_rejepoch(EEG, find(lengths),0); fprintf(log_file,'%.2f - Rejected %d epochs',toc,length(find(lengths))); fprintf(log_file,' %d',find(lengths)); fprintf(log_file,'.\n'); EEG.saved='no'; end if (do_saves), EEG = pop_saveset(EEG,'savemode','resave'); end %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % Average reference % %%%%%%%%%%%%%%%%%%%%% if (do_reref && ~o.ica_options.keep_ICA) if ~o.channel_options.interp_after_ica EEG = h_pop_reref(EEG, [], 'exclude',ext_chans, 'refstate', ref_chan); else EEG = h_pop_reref(EEG, [], 'exclude',[ext_chans chans_to_interp], 'refstate', ref_chan); end end %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % ICA options % %%%%%%%%%%%%%%% % 1 ICA on or off (1 / 0) % 2 Auto component rejection on or off (1 / 0) % 3 Radius for component rejection hypersphere (integer > 0) % 4 EOG channels (vector of integers) %%%%%%%%%%%%%%% do_ica = o.ica_options.run_ica; k_value = o.ica_options.k_value; do_component_rejection = o.ica_options.component_rejection_on; EOG_chans = o.ica_options.EOG_channels; ica_chans = o.ica_options.ica_channels; %%%%%%%%%% % Do ICA % %%%%%%%%%% if do_ica && (~o.ica_options.keep_ICA || isempty(EEG.icaweights)) num_pca = min(floor(sqrt(size(EEG.data(:,:),2) / k_value)),(size(EEG.data,1) - length(chans_to_interp) - 1)); num_pca = min(num_pca,length(setdiff(ica_chans,chans_to_interp))); if (o.channel_options.interp_after_ica) %EEG = pop_runica(EEG, 'icatype', 'runica', 'dataset',1, 'chanind',setdiff(ica_chans,chans_to_interp),'options',{'extended',1,'pca',num_pca}); ica_chans=intersect(setdiff(ica_chans,chans_to_interp),union(eeg_chans,ext_chans)); EEG = pop_runica(EEG, 'dataset',1, 'chanind',setdiff(ica_chans,chans_to_interp),'options',{'extended',1,'pca',num_pca}); else %EEG = pop_runica(EEG, 'icatype', 'runica', 'dataset',1, 'chanind',ica_chans,'options',{'extended',1,'pca',num_pca}); ica_chans=intersect(ica_chans,union(eeg_chans,ext_chans)); EEG = pop_runica(EEG, 'dataset',1, 'chanind',ica_chans,'options',{'extended',1,'pca',num_pca}); end EEG.saved='no'; fprintf(log_file,'%.2f - Ran ICA.\n',toc); end if (do_saves), EEG = pop_saveset(EEG,'savemode','resave'); end if save_before_ica_rej EEGBAK=EEG; EEGBAK.setname = ['pre_comp_rej_' EEG.setname]; pop_saveset(EEGBAK,'filename',['4_pre_comp_rej_' EEG.filename],'filepath',[filepath filesep 'Intermediate'],'savemode','onefile'); clear EEGBAK; end %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % Component rejection section % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % Also includes topoplots % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% if do_component_rejection && ~isempty(EEG.icaweights) EEG = eeg_checkset(EEG); original_name=EEG.setname; if do_lopass list_properties = component_properties(EEG,EOG_chans,[w_l-(t_l/2) w_l+(t_l/2)]); elseif ~isempty(o.ica_options.lopass_freq) && o.ica_options.lopass_freq~=0 list_properties = component_properties(EEG,EOG_chans,[o.ica_options.lopass_freq-5 o.ica_options.lopass_freq+5]); else list_properties = component_properties(EEG,EOG_chans); o.ica_options.rejection_options.measure(2)=0; end [lengths] = min_z(list_properties,o.ica_options.rejection_options); bad_comps=find(lengths); % Plot stuff if (o.ica_options.IC_images) p=1; activations=eeg_getica(EEG); perc_vars = var(activations(:,:),[],2); perc_vars = 100*perc_vars./sum(perc_vars); for u=1:size(EEG.icawinv,2) if ~mod(u-1,16) if (u~=1) saveas(h,sprintf('%s%sIntermediate%sComponents_%d.png',filepath,filesep,filesep,p)); p=p+1; close(h); end h=figure; end subplot(4,4,1+mod(u-1,16)); % if (size(EEG.icawinv,1)~=length(EEG.chanlocs)) % topoplot(EEG.icawinv(:,u),EEG.chanlocs(setdiff(1:length(EEG.chanlocs),chans_to_interp))); topoplot(EEG.icawinv(:,u),EEG.chanlocs(EEG.icachansind)); % else % topoplot(EEG.icawinv(:,u),EEG.chanlocs); %end title(sprintf('Component %d\n%.1f%% variance',u,perc_vars(u))); if ~isempty(find(bad_comps==u, 1)) c=get(h,'Children'); c2=get(c(1),'Children'); set(c2(5),'FaceColor',[0.6 0 0]); x=get(c2(5),'XData'); x(1:end/2)=1.5*(x(1:end/2)); set(c2(5),'XData',x); y=get(c2(5),'YData'); y(1:end/2)=1.5*(y(1:end/2)); set(c2(5),'YData',y); end end %p=p+1; saveas(h,sprintf('%s%sIntermediate%sComponents_%d.png',filepath,filesep,filesep,p)); if ~isempty(h) close(h); end end % Reject if ~isempty(find(lengths,1)) fprintf('Rejecting components'); fprintf(' %d',find(lengths)); fprintf('.\n'); EEG = pop_subcomp(EEG, find(lengths), 0); fprintf(log_file,'%.2f - Rejected %d components',toc,length(find(lengths))); fprintf(log_file,' %d',find(lengths)); fprintf(log_file,'.\n'); else fprintf('Rejected no components.\n'); fprintf(log_file,'%.2f - Rejected no components.\n',toc); end EEG.setname=original_name; EEG.saved='no'; elseif ~isempty(EEG.icawinv) && o.ica_options.IC_images activations=eeg_getica(EEG); perc_vars = var(activations(:,:),[],2); perc_vars = 100*perc_vars./sum(perc_vars); p=1; for u=1:size(EEG.icawinv,2) if ~mod(u-1,16) if (u~=1) saveas(h,sprintf('%s%sIntermediate%sComponents_%d.png',filepath,filesep,filesep,p)); p=p+1; close(h); end h=figure; end subplot(4,4,1+mod(u-1,16)); topoplot(EEG.icawinv(:,u),EEG.chanlocs); title(sprintf('Component %d\n%.1f%% variance',u,perc_vars(u))); end %p=p+1; saveas(h,sprintf('%s%sIntermediate%sComponents_%d.png',filepath,filesep,filesep,p)); if ~isempty(h) close(h); end end if (do_saves), EEG = pop_saveset(EEG,'savemode','resave'); end if save_before_epoch_interp EEGBAK=EEG; EEGBAK.setname = ['pre_epoch_interp_' EEG.setname]; pop_saveset(EEGBAK,'filename',['5_pre_epoch_interp_' EEG.filename],'filepath',[filepath filesep 'Intermediate'],'savemode','onefile'); clear EEGBAK; end %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % Interpolation section part 2 % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% if o.channel_options.interp_after_ica if ~isempty(chans_to_interp) fprintf('Interpolating channel(s)'); fprintf(' %d',chans_to_interp); fprintf('.\n'); EEG = h_eeg_interp_spl(EEG,chans_to_interp,ext_chans); EEG.saved='no'; fprintf(log_file,'%.2f - Interpolated channels',toc); fprintf(log_file,' %d',chans_to_interp); fprintf(log_file,'.\n'); end end %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % Epoch interpolation section % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% do_epoch_interp=o.epoch_interp_options.epoch_interpolation_on; if do_epoch_interp && length(size(EEG.data)) > 2 status = ''; lengths_ep=cell(1,size(EEG.data,3)); for v=1:size(EEG.data,3) list_properties = single_epoch_channel_properties(EEG,v,eeg_chans); lengths_ep{v}=eeg_chans(logical(min_z(list_properties,o.epoch_interp_options.rejection_options))); status = [status sprintf('%d: ',v) sprintf('%d ',lengths_ep{v}) sprintf('\n')]; end EEG=h_epoch_interp_spl(EEG,lengths_ep,ext_chans); EEG.saved='no'; epoch_interps_log_file=fopen([filepath filesep filename '_epoch_interpolations.txt'],'a'); fprintf(epoch_interps_log_file,'%s',status); fclose(epoch_interps_log_file); fprintf(log_file,'%.2f - Did per-epoch interpolation cleanup.\n',toc); fprintf(log_file,['See ' filename(1:end-4) '_epoch_interpolations.txt for details.\n']); end if ~isempty(o.channel_options.op_ref_chan) EEG = h_pop_reref(EEG, o.channel_options.op_ref_chan, 'exclude',ext_chans, 'refstate', [], 'keepref', 'on'); end if (do_saves), EEG = pop_saveset(EEG,'savemode','resave'); end if using_ALLEEG fprintf('Done with ALLEEG(%d) - %s.\nTook %d seconds.\n',o.file_options.current_file_num,EEG.setname,toc); else fprintf('Done with file %s.\nTook %d seconds.\n',[filepath filesep filename extension],toc); end fprintf(log_file,'%.2f - Finished.\n',toc); if (size(EEG.data,3>1)) fprintf(log_file,'Final baseline variance: %.2f.\n',median(var(mean(EEG.data(:,1:round(EEG.srate*-1*EEG.xmin),:),3),[],2))); % More stats here! end fclose(log_file); if (using_ALLEEG) assignin('base','FASTER_TMP_EEG',EEG); if o.file_options.overwrite_ALLEEG evalin('base',sprintf('ALLEEG(%d)=FASTER_TMP_EEG; clear FASTER_TMP_EEG',o.file_options.current_file_num)); else evalin('base','[ALLEEG EEG CURRENTSET] = eeg_store(ALLEEG, FASTER_TMP_EEG);clear FASTER_TMP_EEG;'); end end catch m=lasterror; EEG_state{1}=evalc('disp(EEG)'); try if ~isempty(fopen(log_file)) frewind(log_file); EEG_state{2}=fscanf(log_file,'%c',inf); try fclose(log_file); catch; end; end catch end EEG_state{3}=option_wrapper; EEG_state{4}=builtin('version'); if exist('eeg_getversion','file') EEG_state{5}=eeg_getversion; else EEG_state{5}=which('eeglab'); end assignin('caller','EEG_state',EEG_state); rethrow(m); end end