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snpm_ui.m
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snpm_ui.m
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function snpm_ui(varargin)
% Set up for general linear model and permutation/rando analysis
% FORMAT snpm_ui
% snpm_ui(job)
%_______________________________________________________________________
%
% snpm_ui sets up the parameters for a non-parametric
% permutation/randomisation analysis. The approach taken with SnPM
% analyses differs from that of SPM. Instead of intiating the analysis
% with one command, an analysis consists of 3 steps:
%
% 1. Configuration of Analysis --- interactive
% 2. Calculation of Raw Statistics --- noninteractive
% 3. Post Processing of Raw Statistics --- interactive
%
% ( In SPM, all of these steps are done with a click to the "Statistics" )
% ( button, though the 3rd step is often redone with "Results" or "SPM{Z}")
%
% The first step is embodied in this function, snpm_ui. snpm_ui
% configures the design matrix and calls "plug in" modules that specify
% how the relabeling is to be done for particular designs.
%
% The result of this function is a mat file, "SnPMcfg.mat", written
% to the present working directory (when using the batch system, the
% present directory is changed to the analysis directory specified).
% This file contains all the
% parameters needed to perform the second step, which is in embodied in
% snpm_cp. Design parameters are displayed in the SPM graphics window,
% and are printed.
%
% When called with a job file, as configured by the SPM batch system, no
% user interaction is required.
%-----------------------------------------------------------------------
%
%-The Prompts Explained
%=======================================================================
%
% 'Select design type...': Choose from the available designs. Use the
% 'User Specifed PlugIn' option to supply your own PlugIn function. Use
% the 'keyboard' option to manually set the required PlugIn variables
% (as defined below under "PlugIn Must Supply the following"). The "User
% Specified" option allows you to select a custom PlugIn file. Note that
% due to a limitation in MatLab, only the name of the PlugIn is used,
% not the directory, so make sure the PlugIn is the first with that name
% on the MATLABPATH. type which <plugin-file-name> at the MatLab prompt
% before starting snpm_ui to check!
%
% - At this point you will be prompted by the PlugIn file;
% - see help for the PlugIn file you selected.
%
% 'FWHM(mm) for Variance smooth': Variance smoothing gives the
% nonparmetric approach more power over the parametric approach for
% low-df analyses. If your design has fewer than 20 degrees of freedom
% variance smoothing is advised. 10 mm FWHM is a good starting point
% for the size of the smoothing kernal. For non-isotropic smoothing,
% enter three numbers: FWHM(x) FWHM(y) FWHM(z), all in millimeters.
%
% If there are enough scans and there is no variance smoothing in the z
% direction, you will be asked...
%
% '# scans: Work volumetrically?': Volumetric means that the entire
% data set is loaded into memory; while this is more efficient than
% iterating over planes it is very memory intensive.
%
% ( Note: If you specify variance smoothing in the z-direction, SnPM )
% ( (in snpm_cp.m) has to work volumetrically. Thus, for moderate to )
% ( large numbers of scans there might not be enough memory to complete )
% ( the calculations. This shouldn't be too much of a problem because )
% ( variance smoothing is only necesary at low df, which usually )
% ( corresponds to a small number of scans. Alternatively, specify only )
% ( in-plane smoothing. )
%
% 'Collect Supra-Threshold stats?': In order to use the permutation
% test on supra-threshold cluster size you have to collect a
% substantial amount of additional data for each permutation. If you
% want to look at cluster size answer yes, but have lots of free space
% (the more permutations, the more space needed). You can however
% delete the SnPM_ST.mat file containing the supra-threshold cluster
% data at a later date without affecting the ability to analyze at the
% voxel level.
%
% The remaining questions all parallel the standard parametric analysis
% of SPM; namely
% 'Select global normalisation' - account for global flow confound
% 'Select global calculation' - how global flow is computed
% 'Threshold masking' - threshold to determine voxels to analyze
% 'Explicit masking' - mask image to set analysis
% 'Grand mean scaling' - Whether to scale overall grand mean
%
%
% Programmers / Hackers help...
%=======================================================================
%
% Variables saved in SnPMcfg.mat
%-----------------------------------------------------------------------
% H condition partition of DesMtx for correctly labeled data
% C covariate partition of DesMtx for correctly labeled data
% B block partition of DesMtx for correctly labeled data
% G confound partition of DesMtx for correctly labeled data
% HCBGnames string matrix of column names of [H C B G]
% P string matrix of Filenames corresponding to observations
% PiCond Permuted conditions matrix, one labelling per row, actual
% labelling on first row
% sPiCond String describing permutations in PiCond
% bhPerms Flag indicating use of "half permutations" trick
% sHCform String for computation of HC design matrix partitions
% permutations indexed by perm in snpm_cp
% iGloNorm Global normalisation code
% sGloNorm String describing Global Normalisation option
% GM Grand mean
% GMscale Scaling coefficients for grand mean scaling
% GX Global means for each scan (after scaling of Grand Mean)
% CONT Contrast (only one)
% THRESH Grey matter threshold, as %age of global mean
% TH Grey matter thresholds for each image
% bVarSm Flag for variance smoothing (Pseudo t-statistics)
% vFWHM FWHM for variance smoothing ([0,0,0] if bVarSm=0)
% sVarSm Sring describing variance Smoothing (empty if bVarSm=0)
% bVolm Flag for volumetric computation (whole volume at once)
% bST Flag for collection of superthreshold info
% sDesFile Name of PlugIn design file
% sDesign Description of PlugIn design
% V Memory mapping handles
% MASK Filename of explicit mask image
% ImMASK Implicit masking; 0=none; 1=zeros are equivalent to NaN
%
% df degrees of freedom due to error
% sDesSave String of PlugIn variables to save to cfg file
% String itself and variables listed within it are saved.
% s_SnPMcfg_save string matrix of all variables saved in SnPMcfg
%
% PlugIn Must Supply the following:
%-----------------------------------------------------------------------
% P - string matrix of Filenames corresponding to observations
% iGloNorm - Global normalisation code, or allowable codes
% - Names of columns of design matrix subpartitions
% PiCond - Permuted conditions matrix, one labelling per row, actual
% labelling on first row
% sPiCond - String describing permutations in PiCond
% sHCform - String for computation of HC design matrix partitions
% permutations indexed by perm in snpm_cp
% CONT - single contrast for examination, a row vector
% sDesign - String defining the design [Defaults to PlugIn description]
% sDesSave - String of PlugIn variables to save to cfg file [Default '']
%
% In addition, non-null portions of the design matrix (i.e. non-null H
% C B G) must be specified along with the respective effect names
% (Hnames, Cnames &c.)
%
%_______________________________________________________________________
% Copyright (C) 2013 The University of Warwick
% Id: snpm_ui.m SnPM13 2013/10/12
% Thomas Nichols, Camille Maumet
%------------------------------functions-called------------------------
% spm_DesMtx
% spm_clf
% spm_figure
% spm_select
% spm_global
% spm_hread
% spm_input
% snpm_MSA2x
% snpm_SSA2x
% snpm_SSC
% spm_str_manip
% spm_vol
%----------------------------- functions-called------------------------
%-Initialise workspace
%-----------------------------------------------------------------------
global defaults
if isempty(defaults), spm_defaults; end
global SnPMdefs
if isempty(SnPMdefs), snpm_defaults; end
if nargin==0
% Traditional mode
Finter = spm_figure('FindWin','Interactive');
Fgraph = spm_figure('FindWin','Graphics');
if isempty(Fgraph), Fgraph=spm_figure('Create','Graphics'); end
spm_clf(Finter), spm_clf(Fgraph)
set(Finter,'Name','SnPM Setup');
BATCH=false;
else
job=varargin{1};
BATCH=true;
if exist(job.dir{1})~=7
mkdir(job.dir{1})
end
cd(job.dir{1})
end
%-Definitions & Design parameters
%=======================================================================
sDesigns=str2mat(...
'SingleSub: Two Sample T test; 2 conditions',...
'SingleSub: Simple Regression; 1 covariate of interest',...
'MultiSub: One Sample T test on differences; 1 condition',...
'MultiSub: Simple Regression; 1 covariate of interest',...
'MultiSub: Paired T test; 2 conditions, 1 scan/condition',...
'MultiSub: Randomized Design Paired T test; 2 conditions',...
'MultiSub: Within Subject ANOVA; multiple scans/subject',...
'2 Groups: Test diff of response; 2 conditions, 1 scan/condition',...
'2 Groups: Two Sample T test; 1 scan/subject',...
'>2 Groups: Between Group ANOVA; 1 scan/subject',...
'User Specified PlugIn',...
'keyboard');
sDesFile=str2mat(...
'snpm_pi_TwoSampTss', ...
'snpm_pi_Corr1S', ...
'snpm_pi_OneSampT', ...
'snpm_pi_Corr', ...
'snpm_pi_PairT', ...
'snpm_pi_PairTrand', ...
'snpm_pi_ANOVAwithinS',...
'snpm_pi_TwoSampPairT', ...
'snpm_pi_TwoSampT', ...
'snpm_pi_ANOVAbtwnS',...
'',...
['clc, fprintf([''SnPM: Setup PlugIn variables by hand...\n',...
'\tsee snpm_ui for PlugIn interface definitions\n',...
'\tType return when done\n\n'']), keyboard']);
%%%
%%% These descriptions and codes must match those in config/snpm_cfg_ui.m
%%%
%-Global normalization (GloNorm)
sGloNorm=str2mat(...
'<no global normalisation>',... %-1
'proportional scaling',... %-2
'AnCova',... %-3
'AnCova {subject-specific}',... %-4
'AnCova {study-specific}'); %-5
%-Global calculation options (GXcalc)
sGXcalc = str2mat(...
'omit',... %-1
'user specified',... %-2
'mean voxel value (within per image fullmean/8 mask)'); %-3
%-Grand mean scaling options (GMsca)
sGMsca = str2mat(...
'<no grand Mean scaling>',... %-1
'scaling of overall grand mean'); %-2
%-Select design type
%=======================================================================
if BATCH
sDesign=job.DesignName;
sDesFile=strrep(job.DesignFile,'bch_ui','pi');
else
DesType = spm_input('Select design type...',1,'m',sDesigns);
sDesign = deblank(sDesigns(DesType,:));
sDesFile = deblank(sDesFile(DesType,:));
if isempty(sDesFile)
sDesFile = spm_select(1,'^.*\.m$','Select SnPM design PlugIn Mfile...');
sDesFile = spm_str_manip(sDesFile,'rtd');
end
end
%-Variable initialisation prior to running PlugIn
%-----------------------------------------------------------------------
iStud=[]; % Study indicator vector
iSubj=[]; % Subject indicator vector
iCond=[]; % Condition indicator vector
iRepl=[]; % Replication indicator vector
iXblk=[]; % Exchangability block indicator vector
H=[]; Hnames='';% Condition partition & effect names
C=[]; Cnames='';% Covariates (of interest)
Cc=[]; % Covariates (of interest) | Required only for covariate
Ccnames=[]; % Names of covariates | by factor interactions
B=[]; Bnames=[];% Block partition & effect names
G=[];Gnames=''; % Covariates (no interest)
Gc=[]; % Covariates (no interest) | Required only for covariate
Gcnames=[]; % Names of covariates | by factor interactions
bST=0; % Flag for collection of superthreshold info
bVarSm=0; % Flag for variance smoothing
vFWHM=[0,0,0]; % FWHM for variance smoothing
sVarSm=''; % String describing Variance Smoothing
bVolm=0; % Flag for volumetric computation
nMax4DefVol=snpm_get_defaults('nMax4DefVol');
% Default to volumetric if less than nMax4DefVol scans
sPiCond=''; % String describing permutations in PiCond
bhPerms=0; % Flag for half permutations. Rest are then their inverses
sDesSave=''; % String of PlugIn variables to save to cfg file
iGXcalc='23'; % Global calculation
iGMsca = '12'; % Grand mean scaling of globals
df1=1; % For F stat, it will be the numerator df; For T stat, it
% will be 1.
%-Run PlugIn design specification module
%=======================================================================
eval(sDesFile);
%-Total #observations
nScan = size(P,1);
%-Get general analysis & data parameters
%=======================================================================
%-Ask about variance smoothing & volumetric computation
%-----------------------------------------------------------------------
vFWHM = job.vFWHM;
if length(vFWHM)==1
vFWHM = vFWHM * ones(1,3);
elseif length(vFWHM)==2
vFWHM = [vFWHM, 0];
else
vFWHM = reshape(vFWHM(1:3),1,3);
end
if ~all(vFWHM==0)
bVarSm=1;
end
if bVarSm
sVarSm = sprintf('Pseudo-t: Variance smoothed with FWHM [%dx%dx%d] mm',vFWHM);
end
%-Decide upon volumetric operation
bVolm = job.bVolm;
if ~bVolm && (vFWHM(3)~=0)
warning('SnPM:MayRunOutOfMemory', ...
sprintf(['Working volumetrically because of smoothing in z (%g).\n'...
'May run out of memory.'],vFWHM(3)));
bVolm=1;
end
%-Ask about collecting Supra-Threshold cluster statistics
%-----------------------------------------------------------------------
bST = ~isfield(job.ST,'ST_none');
% Add: get primary threshold for STC analysis if requested
if bST
if ~bVolm
warning('SnPM:CannotDefineThreshVolumetrically', ...
sprintf('Note: Cannot define threshold now, because not working volumetrically\n'));
pU_ST_Ut=-1; % Define the threshold later
else
pU_ST_Ut = ~isfield(job.ST,'ST_later');
if pU_ST_Ut % Define the threshold right now
pU_ST_Ut = job.ST.ST_U;
else
pU_ST_Ut=-1; % Define the threshold later
end
end
else
pU_ST_Ut=NaN;
end
%-Global normalization options
%-----------------------------------------------------------------------
iGloNorm = job.globalm.glonorm;
sGloNorm=deblank(sGloNorm(iGloNorm,:));
%-Get value to be assigned to grand mean:
%-----------------------------------------------------------------------
if iGloNorm==2 % Proportional scaling
iGMsca = 2;%CHANGED from 1 to 2 %-grand mean scaling implicit in PropSca GloNorm
% TODO: must be set otherwise prop scaling alone in Batch mode lead to error
% job.globalm.gmsca.gmscv = ; % By default use mean
else % No global normalisation or ANCOVA
iGMsca = 1 + isfield(job.globalm.gmsca,'gmsca_yes');
end
if (iGMsca==2) % CHANGED from 1 to 2 as should not ask for a value if grand mean scaling is not required.
if (iGloNorm==2) % Proportional scaling
str = 'PropSca global mean to';
else
str = [strrep(sGMsca(iGMsca,:),'scaling of','scale'),' to'];
end
% As in SPM:
switch char(fieldnames(job.globalm.gmsca))
case 'gmsca_yes'
% Proportionally scale to this value
GM = job.globalm.gmsca.gmsca_yes.gmscv;
case 'gmsca_no'
GM = 50;
end
elseif (iGMsca==1) % No grand mean scaling
GM = 0;
end
%-Get globals
%-----------------------------------------------------------------------
if (iGloNorm==1) && (iGMsca==1)
% No need for globals, omit
iGXcalc = 1;
elseif isfield(job.globalc,'g_omit')
%iGXcalc=1;
% Global needed and none requested, force iGXcalc to grand mean (3)
iGXcalc=3;
elseif isfield(job.globalc,'g_user')
iGXcalc=2;
GX = job.globalc.g_user.global_uval;
rg = GX;
if length(GX) ~= nScan
error('SnPM:InvalidGlobals', ['User-specified globals length [%d] doesn''t match number of' ...
' scans [%d]'],length(GX),nScan);
end
elseif isfield(job.globalc,'g_mean')
iGXcalc=3;
end
sGXcalc=deblank(sGXcalc(iGXcalc,:));
%-Get threshold defining voxels to analyse
%-----------------------------------------------------------------------
if isfield(job.masking.tm,'tm_none')
iTHRESH=1;
THRESH = -Inf;
sThresh = 'None';
elseif isfield(job.masking.tm,'tmr')
iTHRESH=2;
THRESH=job.masking.tm.tmr.rthresh;
sThresh=sprintf('Relative (%g)',THRESH);
% As in SPM if relative thresholding then calculation of globals is
% implied
if iGXcalc~=2
iGXcalc = 3;
end
elseif isfield(job.masking.tm,'tma')
iTHRESH=3;
THRESH=job.masking.tm.tma.athresh;
sThresh = sprintf('Absolute (%g)',THRESH);
end
%-Implicit Masking - Batch only!
%-----------------------------------------------------------------------
ImMASK=job.masking.im;
%-Get analysis mask
%-----------------------------------------------------------------------
MASK = job.masking.em{1};
%=======================================================================
%-Computation
%=======================================================================
%-Condition Cc & Gc "Shadow" partitions if no FxC interactions
% These store the covariate values for printing only
%-----------------------------------------------------------------------
if (isempty(Cc) && ~isempty(C)), Cc=C; Ccnames=Cnames; end
if (isempty(Gc) && ~isempty(G)), Gc=G; Gcnames=Gnames; end
%-Examine images
%=======================================================================
%-MMap image files
V = spm_vol(P);
%-Check compatability of images
spm_check_orientations(V);
%-Get ORIGIN, etc
DIM = [V(1).dim(1) V(1).dim(2) V(1).dim(3)]';
M=V(1).mat(1:3, 1:3);
VOX=sqrt(diag(M'*M))';
MAT = V(1).mat;
IMAT = inv(MAT);
ORIGIN = IMAT(1:3,4);
%-Global calculation
%-----------------------------------------------------------------------
if iGXcalc==2
%-User specified globals
elseif iGXcalc==3
%-Compute global values
rg = zeros(nScan,1);
for i = 1:nScan, rg(i)=spm_global(V(i)); end
if any(~isfinite(rg))
disp(rg)
error('SnPM:NaNGlobal', 'Global computation returned NaN! Cannot continue')
end
GX = rg;
elseif iGXcalc==1
rg = [];
GX = [];
end
%-Scale scaling coefficients so that Grand mean, mean(GX), is = GM (if GM~=0)
% Since images are unmapped, this must be replicated in snpm_cp
% Done here to provide check on V's in snpm_cp
if GM ~= 0
GMscale = GM/mean(GX);
for i = 1:nScan
V(i).pinfo(1:2,:) = V(i).pinfo(1:2,:) * GMscale;
end
GX = GX * GMscale;
else
GMscale = 1;
end
%-Compute Grey matter threshold for each image
if (iTHRESH==1) || (iTHRESH==3)
% No threshold or Absolute threshold
TH = repmat(THRESH,nScan,1);
elseif (iTHRESH==2)
% Relative threshold
TH = THRESH * GX;
else
error('SnPM:InvalidiTHRESH', ['Wrong value for iTHRESH: ', num2str(iTHRESH)])
end
%-Construct Global part of covariates of no interest partition.
%-Centre global means if included in AnCova models, by mean correction.
%=======================================================================
Gc = [Gc,GX];
if isempty(Gcnames), Gcnames = 'Global';
else, Gcnames = str2mat(Gcnames,'Global'); end
if iGloNorm == 1 %-No global adjustment
%-----------------------------------------------------------------------
elseif iGloNorm == 2 %-Proportional scaling
%-----------------------------------------------------------------------
% Since images are unmapped, this must be replicated in snpm_cp
% Done here to provide check on V's in snpm_cp
for i = 1:nScan
V(i).pinfo(1:2,:) = GM*V(i).pinfo(1:2,:)/GX(i);
end
elseif iGloNorm == 3 %-AnCova
%-----------------------------------------------------------------------
G = [G,(GX - mean(GX))];
if isempty(Gnames), Gnames = 'Global';
else, Gnames = str2mat(Gnames,'Global'); end
elseif iGloNorm == 4 %-AnCova by subject
%-----------------------------------------------------------------------
[GL,GLnames] = spm_DesMtx([iSUBJ',GX-mean(GX)],'FxC',['SUBJ ';'Global']);
G = [G,GL];
if isempty(Gnames), Gnames = GLnames;
else, Gnames = str2mat(Gnames,GLnames); end
elseif iGloNorm == 5 %-AnCova by study
%-----------------------------------------------------------------------
[GL,GLnames] = spm_DesMtx([iStud',GX-mean(GX)],'FxC',['Stud ';'Global']);
G = [G,GL];
if isempty(Gnames), Gnames = GLnames;
else, Gnames = str2mat(Gnames,GLnames); end
else
%-----------------------------------------------------------------------
error('SnPM:InvalidiGloNorm', sprintf('%cError: invalid iGloNorm option\n',7))
end % (if)
%=======================================================================
%-Ensure validity of contrast of condition effects, zero pad
%-----------------------------------------------------------------------
%-Only a single contrast
if size(CONT,1)==1
if size(H,2)>1
CONT(1:size(H,2)) = CONT(1:size(H,2)) - mean(CONT(1:size(H,2)));
end
end
%-Zero pad for B & G partitions.
% (Note that we trust PlugIns to create valid contrasts for [H C])
CONT = [CONT, zeros(size(CONT,1),size([B G],2))];
%-Construct full design matrix and name matrices for display
%-----------------------------------------------------------------------
[nHCBG,HCBGnames] = spm_DesMtx('Sca',H,Hnames,C,Cnames,B,Bnames,G,Gnames);
%-Setup is complete - save SnPMcfg Mat file
%-----------------------------------------------------------------------
s_SnPMcfg_save = ['s_SnPMcfg_save H C B G HCBGnames P PiCond ',...
'sPiCond bhPerms sHCform iGloNorm sGloNorm GM rg GX GMscale CONT ',...
'THRESH MASK ImMASK TH bVarSm vFWHM sVarSm bVolm bST sDesFile sDesign ',...
'V pU_ST_Ut df1 ', ...
'sDesSave ',sDesSave];
eval(['save SnPMcfg.mat ',s_SnPMcfg_save])
if ~spm_get_defaults('cmdline')
%=======================================================================
%-Display parameters
%=======================================================================
if BATCH
% OK, only _now_ activate the graphics... so if we crash here, there's
% nothing lost
Finter = spm_figure('FindWin','Interactive');
Fgraph = spm_figure('FindWin','Graphics');
if isempty(Fgraph), Fgraph=spm_figure('Create','Graphics'); end
spm_clf(Finter), spm_clf(Fgraph)
end
%-Muck about a bit to set flags for various indicators - handy for later
bMStud=~isempty(iStud);
bMSubj=~isempty(iSubj);
bMCond=~isempty(iCond);
bMRepl=~isempty(iRepl);
bMXblk=~isempty(iXblk);
%-Compute common path components - all paths will begin with file separator
%-----------------------------------------------------------------------
d = max(find(P(1,1:find(~all(P == ones(nScan,1)*P(1,:)), 1 )-1)==filesep)) - 1;
CPath = P(1,1:d);
Q = P(:,d+1:size(P,2));
%-Display data parameters
%=======================================================================
figure(Fgraph); spm_clf; axis off
text(0.30,1.02,'Statistical analysis','Fontsize',16,'Fontweight','Bold');
text(-0.10,0.85,'Scan Index','Rotation',90)
if bMStud, text(-0.05,0.85,'Study', 'Rotation',90); end
if bMSubj, text(+0.00,0.85,'Subject', 'Rotation',90); end
if bMCond, text(+0.05,0.85,'Condition', 'Rotation',90); end
if bMRepl, text(+0.10,0.85,'Replication','Rotation',90); end
if bMXblk, text(+0.15,0.85,'Exchange Blk','Rotation',90); end
x0 = 0.20; y0 = 0.83;
dx = 0.15; dy = 0.02;
x = x0;
for i = 1:size(Cc,2)
text(x + 0.02,0.85,Ccnames(i,:),'Rotation',90);
x = x + dx; end
for i = 1:size(Gc,2)
text(x + 0.02,0.85,Gcnames(i,:),'Rotation',90);
x = x + dx; end
text(x,0.92,'Base directory:','FontSize',10,'Fontweight','Bold');
text(x,0.90,CPath,'FontSize',10,'interpreter','none');
text(x,0.87,'Filename Tails');
y = y0;
for i = 1:nScan
text(-0.12,y,sprintf('%02d :',i));
if bMStud, text(-0.06,y,sprintf('%2d',iStud(i))); end
if bMSubj, text(-0.01,y,sprintf('%2d',iSubj(i))); end
if bMCond, text(+0.04,y,sprintf('%2d',iCond(i))); end
if bMRepl, text(+0.09,y,sprintf('%2d',iRepl(i))); end
if bMXblk, text(+0.14,y,sprintf('%2d',iXblk(i))); end
x = x0;
for j = 1:size(Cc,2)
text(x,y,sprintf('%-8.6g',Cc(i,j)),'FontSize',10)
x = x + dx; end
for j = 1:size(Gc,2)
text(x,y,sprintf('%-8.6g',Gc(i,j)),'FontSize',10)
x = x + dx; end
text(x,y,Q(i,:),'FontSize',10,'interpreter','none');
y = y - dy;
if y < 0
spm_print
spm_clf; axis off
y = y0;
text(0.16,1.02,['Statistical analysis (continued)'],...
'Fontsize',16,'Fontweight','Bold');
end
end
%-Print miscellaneous data parameters
%-----------------------------------------------------------------------
y = y - dy;
dy = dy*1.2;
if (GM~=0)
text(0,y,sprintf(['Images scaled to a grand mean of %g'],GM))
y = y - dy;
end
text(0,y,sprintf(...
'Analysis threshold is %3.0f%% of the whole brain mean',THRESH*100))
spm_print
%-Display design parameters
%=======================================================================
figure(Fgraph); spm_clf(Fgraph); axis off
text(0.30,1.02,'Design Matrix','Fontsize',16,'Fontweight','Bold');
%-Label the effects
%-----------------------------------------------------------------------
hDesMtx = axes('Position',[0.2 0.3 0.6 0.5]);
image((nHCBG + 1)*32);
ylabel('Observations')
set(hDesMtx,'XTick',[],'XTickLabel','')
hEfLabs = axes('Position',[0.2 0.82 0.6 0.1],'Visible','off');
y = 0.1;
dx = 1/size(nHCBG,2);
for i = 1:size(nHCBG,2)
text((i - 0.5)*dx,y,deblank(HCBGnames(i,:)),...
'Fontsize',8,'Rotation',90)
end
%-Display non-parametric analysis summary
%-----------------------------------------------------------------------
hPramAxes=axes('Position',[0.05 0.08 0.8 0.20],'Visible','off');
text(0,1.00,sDesign,'Fontsize',10);
text(0,0.90,['SnPM design file: ',sDesFile],'Fontsize',10);
text(0,0.80,sPiCond,'Fontsize',10);
text(0,0.70,['Global normalisation: ',deblank(sGloNorm)],'Fontsize',10);
text(0,0.60,['Threshold masking: ',deblank(sThresh)],'Fontsize',10);
%-Display parameter summary
%-----------------------------------------------------------------------
text(0,.5,'Parameters:','Fontsize',10,'Fontweight','Bold');
text(0,.4,sprintf(['%d Condition + %d Covariate ',...
'+ %d Block + %d Confound'],...
size(H,2),size(C,2),size(B,2),size(G,2)),...
'Fontsize',10);
text(0,.3,sprintf(['= %d parameters, having %d degrees of freedom, ',...
'giving %d residual df (%d scans).'],...
size([H C B G],2),rank([H C B G]),nScan-rank([H C B G]),nScan),...
'Fontsize',10);
if (bVarSm), text(0,0.2,sVarSm,'Fontsize',10);
end
spm_print
%-Clear interactive window
%-----------------------------------------------------------------------
spm_clf(Finter)
end