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juliankosciessa
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eegmp_analysis
DOI
10.12751/g-node.98d6ks
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b2a_taskPLS_novelty_frontal_erp_plotLV1.m

b2a_taskPLS_novelty_frontal_erp_plotLV1.m 6.5 KB
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  1. % Create an overview plot featuring the results of the multivariate PLS
    2. 

  2. % comparing spectral changes during the stimulus period under load
    3. 

  3. 

  4. clear all; cla; clc;
    5. 

  5. 

  6. currentFile = mfilename('fullpath');
    7. 

  7. [pathstr,~,~] = fileparts(currentFile);
    8. 

  8. cd(fullfile(pathstr,'..'))
    9. 

  9. rootpath = pwd;
    10. 

  10. 

  11. pn.data         = fullfile(rootpath, 'data', 'stats');
    12. 

  12. pn.figures      = fullfile(rootpath, 'figures');
    13. 

  13. pn.tools        = fullfile(rootpath, 'tools');
    14. 

  14.     addpath(genpath(fullfile(pn.tools, '[MEG]PLS', 'MEGPLS_PIPELINE_v2.02b')))
    15. 

  15.     addpath(fullfile(pn.tools, 'fieldtrip')); ft_defaults;
    16. 

  16.     addpath(genpath(fullfile(pn.tools, 'RainCloudPlots')));
    17. 

  17.     addpath(fullfile(pn.tools, 'BrewerMap'));
    18. 

  18.     addpath(fullfile(pn.tools, 'winsor'));
    19. 

  19. 

  20. % set custom colormap
    21. 

  21. cBrew = brewermap(500,'RdBu');
    22. 

  22. cBrew = flipud(cBrew);
    23. 

  23. colormap(cBrew)
    24. 

  24. 

  25. load(fullfile(pn.data, 'c01_taskpls_erp.mat'),...
    26. 

  26.     'stat', 'result', 'lvdat', 'lv_evt_list', 'num_chans', 'num_freqs', 'num_time')
    27. 

  27. load(fullfile(rootpath, 'data','erp', ['sub-001_erp.mat']));
    28. 

  28. elec = erp.scene_category{1}.elec;
    29. 

  29. 

  30. result.perm_result.sprob
    31. 

  31. 

  32. indLV = 1;
    33. 

  33. 

  34. lvdat = reshape(result.boot_result.compare_u(:,indLV), num_chans, num_freqs, num_time);
    35. 

  35. stat.prob = lvdat;
    36. 

  36. stat.mask = lvdat > 3 | lvdat < -3;
    37. 

  37. 

  38. % maskNaN = double(stat.mask);
    39. 

  39. % maskNaN(maskNaN==0) = NaN;
    40. 

  40. 

  41. %% invert solution
    42. 

  42. 

  43. % stat.mask = stat.mask;
    44. 

  44. % stat.prob = stat.prob.*-1;
    45. 

  45. % result.vsc = result.vsc.*-1;
    46. 

  46. % result.usc = result.usc.*-1;
    47. 

  47. 

  48. h = figure('units','centimeter','position',[0 0 15 10]);
    49. 

  49. set(gcf,'renderer','Painters')
    50. 

  50. statsPlot = [];
    51. 

  51. statsPlot = cat(1, statsPlot,squeeze(nanmax(abs(stat.prob(1:64,:,:)),[],1)));
    52. 

  52. plot(stat.time,statsPlot, 'k')
    53. 

  53. xlabel('Time [s from stim onset]'); ylabel('max abs BSR');
    54. 

  54. title({'ERP changes'; ['p = ', num2str(round(result.perm_result.sprob(indLV),4))]})
    55. 

  55. set(findall(gcf,'-property','FontSize'),'FontSize',18)
    56. 

  56. % figureName = ['b01_pls_traces'];
    57. 

  57. % saveas(h, fullfile(pn.figures, figureName), 'epsc');
    58. 

  58. % saveas(h, fullfile(pn.figures, figureName), 'png');
    59. 

  59. 

  60. 

  61. h = figure('units','centimeter','position',[0 0 15 10]);
    62. 

  62. set(gcf,'renderer','Painters')
    63. 

  63. statsPlot = [];
    64. 

  64. statsPlot = cat(1, statsPlot,squeeze(mean(stat.prob(1:64,:,:),1)));
    65. 

  65. plot(stat.time,statsPlot, 'k')
    66. 

  66. xlabel('Time [s from stim onset]'); ylabel('mean BSR');
    67. 

  67. title({'ERP changes'; ['p = ', num2str(round(result.perm_result.sprob(indLV),4))]})
    68. 

  68. set(findall(gcf,'-property','FontSize'),'FontSize',18)
    69. 

  69. %xlim([0 0.3])
    70. 

  70. % figureName = ['b01_pls_traces'];
    71. 

  71. % saveas(h, fullfile(pn.figures, figureName), 'epsc');
    72. 

  72. % saveas(h, fullfile(pn.figures, figureName), 'png');
    73. 

  73. 

  74. %% plot multivariate topographies
    75. 

  75. 

  76. h = figure('units','centimeters','position',[0 0 10 10]);
    77. 

  77. set(gcf,'renderer','Painters')
    78. 

  78. 

  79. cfg = [];
    80. 

  80. cfg.layout = 'biosemi64.lay';
    81. 

  81. cfg.parameter = 'powspctrm';
    82. 

  82. cfg.comment = 'no';
    83. 

  83. cfg.colormap = cBrew;
    84. 

  84. cfg.colorbar = 'EastOutside';
    85. 

  85. 

  86. plotData = [];
    87. 

  87. plotData.label = elec.label; % {1 x N}
    88. 

  88. plotData.dimord = 'chan';
    89. 

  89. cfg.zlim = [-2 2]; 
    90. 

  90. cfg.figure = h;
    91. 

  91. plotData.powspctrm = squeeze(nanmean(stat.mask(:,:,:).*...
    92. 

  92.     stat.prob(:,:,:),3)); 
    93. 

  93. ft_topoplotER(cfg,plotData);
    94. 

  94. cb = colorbar('location', 'EastOutside'); set(get(cb,'ylabel'),'string','Mean BSR');
    95. 

  95. figureName = ['b01_lv1'];
    96. 

  96. % saveas(h, fullfile(pn.figures, figureName), 'epsc');
    97. 

  97. % saveas(h, fullfile(pn.figures, figureName), 'png');
    98. 

  98. 

  99. %% plot using raincloud plot
    100. 

  100. 

  101. groupsizes=result.num_subj_lst;
    102. 

  102. conditions=lv_evt_list;
    103. 

  103. conds = {'old'; 'new'};
    104. 

  104. condData = []; uData = [];
    105. 

  105. for indGroup = 1
    106. 

  106.     if indGroup == 1
    107. 

  107.         relevantEntries = 1:groupsizes(1)*numel(conds);
    108. 

  108.     elseif indGroup == 2
    109. 

  109.         relevantEntries = groupsizes(1)*numel(conds)+1:...
    110. 

  110.              groupsizes(1)*numel(conds)+groupsizes(2)*numel(conds);
    111. 

  111.     end
    112. 

  112.     for indCond = 1:numel(conds)
    113. 

  113.         targetEntries = relevantEntries(conditions(relevantEntries)==indCond);        
    114. 

  114.         condData{indGroup}(indCond,:) = result.vsc(targetEntries,indLV);
    115. 

  115.         uData{indGroup}(indCond,:) = result.usc(targetEntries,indLV);
    116. 

  116.     end
    117. 

  117. end
    118. 

  118. 

  119. %% plot RainCloudPlot (within-subject centered)
    120. 

  120. 

  121. cBrew(1,:) = 2.*[.3 .1 .1];
    122. 

  122. cBrew(2,:) = [.6 .6 .6];
    123. 

  123. 

  124. idx_outlier = cell(1); idx_standard = cell(1);
    125. 

  125. for indGroup = 1
    126. 

  126.     dataToPlot = uData{indGroup}';
    127. 

  127.     % define outlier as lin. modulation that is more than three scaled median absolute deviations (MAD) away from the median
    128. 

  128.     X = [1 1; 1 2]; b=X\dataToPlot'; IndividualSlopes = b(2,:);
    129. 

  129.     outliers = isoutlier(IndividualSlopes, 'median');
    130. 

  130.     idx_outlier{indGroup} = find(outliers);
    131. 

  131.     idx_standard{indGroup} = find(outliers==0);
    132. 

  132. end
    133. 

  133. 

  134. h = figure('units','centimeter','position',[0 0 25 10]);
    135. 

  135. for indGroup = 1
    136. 

  136.     dataToPlot = uData{indGroup}';
    137. 

  137.     % read into cell array of the appropriate dimensions
    138. 

  138.     data = []; data_ws = [];
    139. 

  139.     for i = 1:2
    140. 

  140.         for j = 1:1
    141. 

  141.             data{i, j} = dataToPlot(:,i);
    142. 

  142.             % individually demean for within-subject visualization
    143. 

  143.             data_ws{i, j} = dataToPlot(:,i)-...
    144. 

  144.                 nanmean(dataToPlot(:,:),2)+...
    145. 

  145.                 repmat(nanmean(nanmean(dataToPlot(:,:),2),1),size(dataToPlot(:,:),1),1);
    146. 

  146.             data_nooutlier{i, j} = data{i, j};
    147. 

  147.             data_nooutlier{i, j}(idx_outlier{indGroup}) = [];
    148. 

  148.             data_ws_nooutlier{i, j} = data_ws{i, j};
    149. 

  149.             data_ws_nooutlier{i, j}(idx_outlier{indGroup}) = [];
    150. 

  150.             % sort outliers to back in original data for improved plot overlap
    151. 

  151.             data_ws{i, j} = [data_ws{i, j}(idx_standard{indGroup}); data_ws{i, j}(idx_outlier{indGroup})];
    152. 

  152.         end
    153. 

  153.     end
    154. 

  154. 

  155.     % IMPORTANT: plot individually centered estimates, stats on uncentered estimates!
    156. 

  156. 

  157.     subplot(1,2,indGroup);
    158. 

  158.     set(gcf,'renderer','Painters')
    159. 

  159.         cla;
    160. 

  160.         cl = cBrew(indGroup,:);
    161. 

  161.         [~, dist] = rm_raincloud_fixedSpacing(data_ws, [.8 .8 .8],1);
    162. 

  162.         h_rc = rm_raincloud_fixedSpacing(data_ws_nooutlier, cl,1,[],[],[],dist);
    163. 

  163.         view([90 -90]);
    164. 

  164.         axis ij
    165. 

  165.     box(gca,'off')
    166. 

  166.     set(gca, 'YTickLabels', {conds{2}; conds{1}});
    167. 

  167.     yticks = get(gca, 'ytick'); ylim([yticks(1)-(yticks(2)-yticks(1))./2, yticks(2)+(yticks(2)-yticks(1))./1.5]);
    168. 

  168. 

  169.     minmax = [min(min(cat(2,data_ws{:}))), max(max(cat(2,data_ws{:})))];
    170. 

  170.     xlim(minmax+[-0.2*diff(minmax), 0.2*diff(minmax)])
    171. 

  171.     ylabel('novelty'); xlabel({'Brainscore'; '[Individually centered]'})
    172. 

  172. 

  173.     % test linear effect
    174. 

  174.     curData = [data_nooutlier{1, 1}, data_nooutlier{2, 1}];
    175. 

  175.     X = [1 1; 1 2]; b=X\curData'; IndividualSlopes = b(2,:);
    176. 

  176.     [~, p, ci, stats] = ttest(IndividualSlopes);
    177. 

  177.     title(['M:', num2str(round(mean(IndividualSlopes),3)), '; p=', num2str(round(p,3))])
    178. 

  178. end
    179. 

  179. % figureName = ['b01_rcp'];
    180. 

  180. % saveas(h, fullfile(pn.figures, figureName), 'epsc');
    181. 

  181. % saveas(h, fullfile(pn.figures, figureName), 'png');
    182.