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examples_dev.m
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examples_dev.m
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%% gramm examples and how-tos
%% Example from the readme
% Here we plot the evolution of fuel economy of new cars bewteen 1970 and 1980 (carbig
% dataset). Gramm is used to easily separate groups on the basis of the number of
% cylinders of the cars (color), and on the basis of the region of origin of
% the cars (subplot columns). Both the raw data (points) and a glm fit with
% 95% confidence interval (line+shaded area) are plotted.
%
% We stat by loading the sample data (structure created from the carbig
% dataset)
load example_data;
%%%
% Create a gramm object, provide x (year of production) and y (fuel economy) data,
% color grouping data (number of cylinders) and select a subset of the data
g=gramm('x',cars.Model_Year,'y',cars.MPG,'color',cars.Cylinders,'subset',cars.Cylinders~=3 & cars.Cylinders~=5);
%%%
% Subdivide the data in subplots horizontally by region of origin using
% facet_grid()
g.facet_grid([],cars.Origin_Region);
%%%
% Plot raw data as points
g.geom_point();
%%%
% Plot linear fits of the data with associated confidence intervals
g.stat_glm();
%%%
% Set appropriate names for legends
g.set_names('column','Origin','x','Year of production','y','Fuel economy (MPG)','color','# Cylinders');
%%%
% Set figure title
g.set_title('Fuel economy of new cars between 1970 and 1982');
%%%
% Do the actual drawing
figure('Position',[100 100 800 400]);
g.draw();
%% Grouping options in gramm
% With gramm there are a lot ways to map groups to visual properties of
% plotted data, or even subplots.
% Providing grouping variables to change visual properties is done in the
% constructor call |gramm()|. Grouping variables that determine subplotting
% are provided by calls to the |facet_grid()| or |facet_wrap()| methods.
% Note that *all the mappings presented below can be combined*, i.e. it's
% possible to previde different variables to each of the options.
%
% In order to plot multiple, diferent gramm objects in the same figure, an array of gramm objects
% is created, and the |draw()| function called at the end on the whole array
clear g
g(1,1)=gramm('x',cars.Horsepower,'y',cars.MPG,'subset',cars.Cylinders~=3 & cars.Cylinders~=5);
g(1,1).geom_point();
g(1,1).set_names('x','Horsepower','y','MPG');
g(1,1).set_title('No groups');
g(1,2)=gramm('x',cars.Horsepower,'y',cars.MPG,'subset',cars.Cylinders~=3 & cars.Cylinders~=5,'color',cars.Cylinders);
g(1,2).geom_point();
g(1,2).set_names('x','Horsepower','y','MPG','color','# Cyl');
g(1,2).set_title('color');
g(1,3)=gramm('x',cars.Horsepower,'y',cars.MPG,'subset',cars.Cylinders~=3 & cars.Cylinders~=5,'lightness',cars.Cylinders);
g(1,3).geom_point();
g(1,3).set_names('x','Horsepower','y','MPG','lightness','# Cyl');
g(1,3).set_title('lightness');
g(2,1)=gramm('x',cars.Horsepower,'y',cars.MPG,'subset',cars.Cylinders~=3 & cars.Cylinders~=5,'size',cars.Cylinders);
g(2,1).geom_point();
g(2,1).set_names('x','Horsepower','y','MPG','size','# Cyl');
g(2,1).set_title('size');
g(2,2)=gramm('x',cars.Horsepower,'y',cars.MPG,'subset',cars.Cylinders~=3 & cars.Cylinders~=5,'marker',cars.Cylinders);
g(2,2).geom_point();
g(2,2).set_names('x','Horsepower','y','MPG','marker','# Cyl');
g(2,2).set_title('marker');
g(2,3)=gramm('x',cars.Horsepower,'y',cars.MPG,'subset',cars.Cylinders~=3 & cars.Cylinders~=5,'linestyle',cars.Cylinders);
g(2,3).geom_line();
g(2,3).set_names('x','Horsepower','y','MPG','linestyle','# Cyl');
g(2,3).set_title('linestyle');
g(3,1)=gramm('x',cars.Horsepower,'y',cars.MPG,'subset',cars.Cylinders~=3 & cars.Cylinders~=5);
g(3,1).facet_grid(cars.Cylinders,[]);
g(3,1).geom_point();
g(3,1).set_names('x','Horsepower','y','MPG','row','# Cyl');
g(3,1).set_title('subplot rows');
g(3,2)=gramm('x',cars.Horsepower,'y',cars.MPG,'subset',cars.Cylinders~=3 & cars.Cylinders~=5);
g(3,2).facet_grid([],cars.Cylinders);
g(3,2).geom_point();
g(3,2).set_names('x','Horsepower','y','MPG','column','# Cyl');
g(3,2).set_title('subplot columns');
figure('Position',[100 100 800 800]);
g.draw();
%% Methods for visualizing Y~X relationships with X as categorical variable
% The following methods can be used when Y data is continuous and X data discrete/categorical.
%
% Here we also use an array of gramm objects in order to have multiple gramm plots
% on the same figure. The gramm objects use the same data, so we copy them after construction using the
% |copy()| method. We also duplicate the whole array of gramm objects
% before drawing in order to demonstrate the use of coord_flip() to
% exchange X and Y axes
clear g
g(1,1)=gramm('x',cars.Origin_Region,'y',cars.Horsepower,'color',cars.Cylinders,'subset',cars.Cylinders~=3 & cars.Cylinders~=5);
g(1,2)=copy(g(1));
g(1,3)=copy(g(1));
g(2,1)=copy(g(1));
g(2,2)=copy(g(1));
g(2,3)=copy(g(1));
%Raw data as scatter plot
g(1,1).geom_point();
g(1,1).set_title('geom_point()');
%Jittered scatter plot
g(1,2).geom_jitter('width',0.4,'height',0);
g(1,2).set_title('geom_jitter()');
%Averages with confidence interval
g(1,3).stat_summary('geom',{'bar','black_errorbar'});
g(1,3).set_title('stat_summary()');
%Boxplots
g(2,1).stat_boxplot();
g(2,1).set_title('stat_boxplot()');
%Violin plots
g(2,2).stat_violin('fill','transparent');
g(2,2).set_title('stat_violin()');
%beeswarm / swarm plots
g(2,3).geom_swarm('point_size',2);
g(2,3).set_title('geom_swarm()');
%These functions can be called on arrays of gramm objects
g.set_names('x','Origin','y','Horsepower','color','# Cyl');
g.set_title('Visualization of Y~X relationships with X as categorical variable');
gf = copy(g);
figure('Position',[100 100 800 550]);
g.draw();
gf.set_title('Visualization of Y~X relationships with X as categorical variable and flipped coordinates');
figure('Position',[100 100 800 550]);
gf.coord_flip();
gf.draw();
%% Methods for visualizing X densities
% The following methods can be used in order to represent the density of a continuous variable. Note that here
% we represent the same data as in the previous figure, this time with Horsepower as X
% (over which the densities are represented), and separating the region of
% origin with subplots.
clear g
g(1,1)=gramm('x',cars.Horsepower,'color',cars.Cylinders,'subset',cars.Cylinders~=3 & cars.Cylinders~=5);
g(1,2)=copy(g(1));
g(2,1)=copy(g(1));
g(2,2)=copy(g(1));
%Raw data as raster plot
g(1,1).facet_grid(cars.Origin_Region,[]);
g(1,1).geom_raster();
g(1,1).set_title('geom_raster()');
%Histogram
g(1,2).facet_grid(cars.Origin_Region,[]);
g(1,2).stat_bin('nbins',8);
g(1,2).set_title('stat_bin()');
%Kernel smoothing density estimate
g(2,1).facet_grid(cars.Origin_Region,[]);
g(2,1).stat_density();
g(2,1).set_title('stat_density()');
% Q-Q plot for normality
g(2,2).facet_grid(cars.Origin_Region,[]);
g(2,2).stat_qq();
g(2,2).axe_property('XLim',[-5 5]);
g(2,2).set_title('stat_qq()');
g.set_names('x','Horsepower','color','# Cyl','row','','y','');
g.set_title('Visualization of X densities');
figure('Position',[100 100 800 550]);
g.draw();
%% Methods for visualizing Y~X relationship with both X and Y as continuous variables
% The following methods can be used when
% both X and Y data are continuous
clear g
%Raw data as scatter plot
g(1,1)=gramm('x',cars.Horsepower,'y',cars.Acceleration,'color',cars.Cylinders,'subset',cars.Cylinders~=3 & cars.Cylinders~=5);
g(1,2)=copy(g(1));
g(1,3)=copy(g(1));
g(2,1)=copy(g(1));
g(2,2)=copy(g(1));
g(1,1).geom_point();
g(1,1).set_title('geom_point()');
%Generalized linear model fit
g(1,2).stat_glm();
g(1,2).set_title('stat_glm()');
%Custom fit with provided function
g(1,3).stat_fit('fun',@(a,b,c,x)a./(x+b)+c,'intopt','functional');
g(1,3).set_title('stat_fit(''fun'',@(a,b,c,x)a./(x+b)+c)');
%Spline smoothing
g(2,1).stat_smooth();
g(2,1).set_title('stat_smooth()');
%Moving average
g(2,2).stat_summary('bin_in',10);
g(2,2).set_title('stat_summary(''bin_in'',10)');
g.set_names('x','Horsepower','y','Acceleration','color','# Cylinders');
%Corner histogram
g(2,3)=gramm('x',(cars.Horsepower-nanmean(cars.Horsepower))/nanstd(cars.Horsepower),'y',-(cars.Acceleration-nanmean(cars.Acceleration))/nanstd(cars.Acceleration),'color',cars.Cylinders,'subset',cars.Cylinders~=3 & cars.Cylinders~=5);
g(2,3).geom_point();
g(2,3).stat_cornerhist('edges',-4:0.2:4,'aspect',0.6);
g(2,3).geom_abline();
g(2,3).set_title('stat_cornerhist()');
g(2,3).set_names('x','z(Horsepower)','y','-z(Acceleration)');
g.set_title('Visualization of Y~X relationship with both X and Y as continuous variables');
figure('Position',[100 100 800 550]);
g.draw();
%% Methods for visualizing custom confidence intervals
% With |geom_interval()| it is possible to plot custom confidence intervals
% by provinding |'ymin'| and |'ymax'| values to |gramm()|. All options to
% display confidence intervals in |stat_summary()| are available, including
% dodging. |'ymin'| and |'ymax'| are absolute, and not given relative to
% |'y'|
cars_summary=rowfun(@(hp)deal(nanmean(hp),bootci(200,@(x)nanmean(x),hp)'),cars(cars.Cylinders~=3 & cars.Cylinders~=5,:),...
'InputVariables',{'Horsepower'},...
'GroupingVariables',{'Origin_Region' 'Cylinders'},...
'OutputVariableNames',{'hp_mean' 'hp_ci'});
clear g
%Bars and error bars
g(1,1)=gramm('x',cars_summary.Origin_Region,'y',cars_summary.hp_mean,...
'ymin',cars_summary.hp_ci(:,1),'ymax',cars_summary.hp_ci(:,2),'color',cars_summary.Cylinders);
g(1,1).set_names('x','Origin','y','Horsepower','color','# Cylinders');
g(1,1).geom_bar('dodge',0.8,'width',0.6);
g(1,1).geom_interval('geom','black_errorbar','dodge',0.8,'width',1);
%points and error bars
g(1,2)=gramm('x',categorical(cars_summary.Cylinders),'y',cars_summary.hp_mean,...
'ymin',cars_summary.hp_ci(:,1),'ymax',cars_summary.hp_ci(:,2),'color',cars_summary.Origin_Region);
g(1,2).set_names('color','Origin','y','Horsepower','x','# Cylinders');
g(1,3)=copy(g(1,2));
g(1,2).set_color_options('map','matlab');
g(1,2).geom_point('dodge',0.2);
g(1,2).geom_interval('geom','errorbar','dodge',0.2,'width',0.8);
%Shaded area
g(1,3).geom_interval('geom','area');
figure('Position',[100 100 800 450]);
g.axe_property('YLim',[-10 190]);
g.draw();
%% Methods for visualizing 2D densities
% The following methods can be used to visualize 2D densities for
% bivariate data
%Create point cloud with two categories
N=10^4;
x=randn(1,N);
y=x+randn(1,N);
test=repmat([0 1 0 0],1,N/4);
y(test==0)=y(test==0)+3;
clear g
% Display points and 95% percentile confidence ellipse
g(1,1)=gramm('x',x,'y',y,'color',test);
g(1,1).set_names('color','grp');
g(1,1).geom_point();
%'patch_opts' can be used to provide more options to the patch() internal
%call
g(1,1).set_point_options('base_size',2);
g(1,1).stat_ellipse('type','95percentile','geom','area','patch_opts',{'FaceAlpha',0.1,'LineWidth',2});
g(1,1).set_title('stat_ellispe()');
%Plot point density as contour plot
g(1,2)=gramm('x',x,'y',y,'color',test);
g(1,2).stat_bin2d('nbins',[10 10],'geom','contour');
g(1,2).set_names('color','grp');
g(1,2).set_title('stat_bin2d(''geom'',''contour'')');
% %Plot density as point size (looks good only when axes have the same
% %scale, hence the 'DataAspectRatio' option, equivalent to axis equal)
% g(2,1)=gramm('x',x,'y',y,'color',test);
% g(2,1).stat_bin2d('nbins',{-10:0.4:10 ; -10:0.4:10},'geom','point');
% g(2,1).axe_property('DataAspectRatio',[1 1 1]);
% g(2,1).set_names('color','grp');
% g(2,1).set_title('stat_bin2d(''geom'',''point'')');
%Plot density as heatmaps (Heatmaps don't work with multiple colors, so we separate
%the categories with facets). With the heatmap we see better the
%distribution in high-density areas
g(2,1)=gramm('x',x,'y',y);
g(2,1).facet_grid([],test);
g(2,1).stat_bin2d('nbins',[20 20],'geom','image');
%g(2,1).set_continuous_color('LCH_colormap',[0 100 ; 100 20 ;30 20]); %Let's try a custom LCH colormap !
g(2,1).set_names('column','grp','color','count');
g(2,1).set_title('stat_bin2d(''geom'',''image'')');
g(2,2)=gramm('x',x,'y',y,'color',test);
g(2,2).geom_point('alpha',0.05);
g(2,2).set_point_options('base_size',6);
g(2,2).set_title('geom_point(''alpha'',0.05)');
g.set_title('Visualization of 2D densities');
figure('Position',[100 100 800 600])
g.draw();
%% Methods for visualizing repeated trajectories
% gramm supports 2D inputs for X and Y data (as 2D array or cell of
% arrays), which is particularly useful for representing repeated
% trajectories. Here for example we generate 50 trajectories, each of
% length 40. The grouping data is then given per trajectory and not per
% data point. Here the color grouping variable is thus given as a 1x50
% cellstr.
%We generate 50 trajectories of length 40, with 3 groups
N=50;
nx=40;
cval={'A' 'B' 'C'};
cind=randi(3,N,1);
c=cval(cind);
x=linspace(0,3,nx);
y=arrayfun(@(c)sin(x*c)+randn(1,nx)/10+x*randn/5,cind,'UniformOutput',false);
clear g
g(1,1)=gramm('x',x,'y',y,'color',c);
g(1,2)=copy(g(1));
g(2,1)=copy(g(1));
g(2,2)=copy(g(1));
g(1,1).geom_point();
g(1,1).set_title('geom_point()');
g(1,2).geom_line();
g(1,2).set_title('geom_line()');
g(2,1).stat_smooth();
g(2,1).set_point_options('base_size',3);
g(2,1).set_title('stat_smooth()');
g(2,2).stat_summary();
g(2,2).set_title('stat_summary()');
g.set_title('Visualization of repeated trajectories ');
figure('Position',[100 100 800 550]);
g.draw();
%% Methods for visualizing repeated densities (e.g. spike densities)
% With the support of 2D inputs for X and gramm's functionality for
% representing the density of data, useful neuroscientific plots can be
% generated when the provided X corresponds to spike trains: raster plots
% and peristimulus time histograms (PSTHs).
%We generate 50 spike trains, with 3 groups
N=50;
cval={'A' 'B' 'C'};
cind=randi(3,N,1);
c=cval(cind);
train_template=[zeros(1,300) ones(1,200)];
%Pseudo-poisson spike trains
spike_train=cell(N,1);
for k=1:N
temp_train=rand*0.05+train_template/(cind(k)*8);
U=rand(size(temp_train));
spike_train{k}=find(U<temp_train);
end
clear g
g(1,1)=gramm('x',spike_train,'color',c);
g(1,1).geom_raster();
g(1,1).set_title('geom_raster()');
g(1,2)=gramm('x',spike_train,'color',c);
g(1,2).stat_bin('nbins',25,'geom','line');
g(1,2).set_title('stat_bin()');
g.set_names('x','Time','y','');
g.set_title('Visualization of spike densities');
figure('Position',[100 100 800 350]);
g.draw();
%% Options for separating groups across subplots with facet_grid()
% To separate groups in different rows and columns of sublots, the grouping
% variable just need to be passed to the
% |facet_grid(goup_rows,group_columns)| function or |facet_wrap(group_columns)|. Both have multiple
% options concerning the scaling of data between subplots.
%
% * By default |'scale','fixed'| all subplots have the same limits
% * |'scale','free_x'|: subplots on the same columns have the same x limits
% * |'scale','free_y'|: subplots on the same rows have the same y limits
% * |'scale','free'|: subplots on the same rows have the same y limits,
% subplots on the same columns have the same x limits
% * |'scale','independent'|: subplots have independent limits
%
% In |facet_grid()|; the |'space'| option allows to set how the subplot axes themselves scale with
% the data. It should be used in conjunction with the corresponding
% |'scale'| option.
% Generating fake data
N=1000;
colval={'A' 'B' 'C'};
rowval={'I' 'II'};
cind=randi(3,N,1);
c=colval(cind);
rind=randi(2,N,1);
r=rowval(rind);
x=randn(N,1);
y=randn(N,1);
x(cind==1 & rind==1)=x(cind==1 & rind==1)*5;
x=x+cind*3;
y(cind==3 & rind==2)=y(cind==3 & rind==2)*3;
y=y-rind*4;
clear g
g(1,1)=gramm('x',x,'y',y,'color',c,'lightness',r);
g(1,2)=copy(g(1));
g(2,1)=copy(g(1));
g(2,2)=copy(g(1));
g(3,1)=copy(g(1));
g(3,2)=copy(g(1));
g(1,1).geom_point();
g(1,1).set_title('No facets');
g(1,2).facet_grid(r,c);
g(1,2).geom_point();
g(1,2).no_legend();
g(1,2).set_title('facet_grid()');
g(2,1).facet_grid(r,c,'scale','free');
g(2,1).geom_point();
g(2,1).no_legend();
g(2,1).set_title('facet_grid(''scale'',''free'')');
g(2,2).facet_grid(r,c,'scale','free','space','free');
g(2,2).geom_point();
g(2,2).no_legend();
g(2,2).set_title('facet_grid(''scale'',''free'',''space'',''free'')');
g(3,1).facet_grid(r,c,'scale','free_x');
g(3,1).geom_point();
g(3,1).no_legend();
g(3,1).set_title('facet_grid(''scale'',''free_x'')');
g(3,2).facet_grid(r,c,'scale','independent');
g(3,2).geom_point();
g(3,2).no_legend();
g(3,2).set_title('facet_grid(''scale'',''independent'')');
g.set_color_options('lightness_range',[40 80],'chroma_range',[80 40]);
g.set_names('column','','row','');
%g.axe_property('color',[0.9 0.9 0.9],'XGrid','on','YGrid','on','GridColor',[1 1 1],'GridAlpha',0.8,'TickLength',[0 0],'XColor',[0.3 0.3 0.3],'YColor',[0.3 0.3 0.3])
gf = copy(g);
figure('Position',[100 100 800 800]);
g.set_title('facet_grid() options');
g.draw();
figure('Position',[100 100 800 800]);
gf.set_title({'facet_grid() options' 'work together with coord_flip()'});
gf.coord_flip();
gf.draw();
%% Options for creating histograms with stat_bin()
% Example of different |'geom'| options:
%
% * |'bar'| (default), where color groups are side-by-side (dodged)
% * |'stacked_bar'|
% * |'line'|
% * |'overlaid_bar'|
% * |'point'|
% * |'stairs'|
%Create variables
x=randn(1200,1)-1;
cat=repmat([1 1 1 2],300,1);
x(cat==2)=x(cat==2)+2;
clear g5
g5(1,1)=gramm('x',x,'color',cat);
g5(1,2)=copy(g5(1));
g5(1,3)=copy(g5(1));
g5(2,1)=copy(g5(1));
g5(2,2)=copy(g5(1));
g5(2,3)=copy(g5(1));
g5(1,1).stat_bin(); %by default, 'geom' is 'bar', where color groups are side-by-side (dodged)
g5(1,1).set_title('''bar'' (default)');
g5(1,2).stat_bin('geom','stacked_bar'); %Stacked bars option
g5(1,2).set_title('''stacked_bar''');
g5(2,1).stat_bin('geom','line'); %Draw lines instead of bars, easier to visualize when lots of categories, default fill to edges !
g5(2,1).set_title('''line''');
g5(2,2).stat_bin('geom','overlaid_bar'); %Overlaid bar automatically changes bar coloring to transparent
g5(2,2).set_title('''overlaid_bar''');
g5(1,3).stat_bin('geom','point');
g5(1,3).set_title('''point''');
g5(2,3).stat_bin('geom','stairs'); %Default fill is edges
g5(2,3).set_title('''stairs''');
g5.set_title('''geom'' options for stat_bin()');
figure('Position',[100 100 800 600]);
g5.draw();
%%
% Example of alternative |'fill'| options
%
% * |'face'|
% * |'all'|
% * |'edge'|
% * |'transparent'|
clear g6
g6(1,1)=gramm('x',x,'color',cat);
g6(1,2)=copy(g6(1));
g6(1,3)=copy(g6(1));
g6(2,1)=copy(g6(1));
g6(2,2)=copy(g6(1));
g6(2,3)=copy(g6(1));
g6(1,1).stat_bin('fill','face');
g6(1,1).set_title('''face''');
g6(1,2).stat_bin('fill','transparent');
g6(1,2).set_title('''transparent''');
g6(1,3).stat_bin('fill','all');
g6(1,3).set_title('''all''');
g6(2,1).stat_bin('fill','edge');
g6(2,1).set_title('''edge''');
g6(2,2).stat_bin('geom','stairs','fill','transparent');
g6(2,2).set_title('''transparent''');
g6(2,3).stat_bin('geom','line','fill','all');
g6(2,3).set_title('''all''');
g6.set_title('''fill'' options for stat_bin()');
figure('Position',[100 100 800 600]);
g6.draw();
%%
% Examples of other histogram-generation options
%
% * Default binning
% * |'normalization','probability'|
% * |'normalization','cumcount'|
% * |'normalization','cdf'|
% * |'edges',-1:0.5:10|
% * |'normalization','countdensity'| and custom edges
clear g7
g7(1,1)=gramm('x',x,'color',cat);
g7(1,2)=copy(g7(1));
g7(1,3)=copy(g7(1));
g7(2,1)=copy(g7(1));
g7(2,2)=copy(g7(1));
g7(2,3)=copy(g7(1));
g7(1,1).stat_bin('geom','overlaid_bar'); %Default binning (30 bins)
%Normalization to 'probability'
g7(2,1).stat_bin('normalization','probability','geom','overlaid_bar');
g7(2,1).set_title('''normalization'',''probability''','FontSize',10);
%Normalization to cumulative count
g7(1,2).stat_bin('normalization','cumcount','geom','stairs');
g7(1,2).set_title('''normalization'',''cumcount''','FontSize',10);
%Normalization to cumulative density
g7(2,2).stat_bin('normalization','cdf','geom','stairs');
g7(2,2).set_title('''normalization'',''cdf''','FontSize',10);
%Custom edges for the bins
g7(1,3).stat_bin('edges',-1:0.5:10,'geom','overlaid_bar');
g7(1,3).set_title('''edges'',-1:0.5:10','FontSize',10);
%Custom edges with non-constand width (normalization 'countdensity'
%recommended)
g7(2,3).stat_bin('geom','overlaid_bar','normalization','countdensity','edges',[-5 -4 -2 -1 -0.5 -0.25 0 0.25 0.5 1 2 4 5]);
g7(2,3).set_title({'''normalization'',''countdensity'',' '''edges'',' '[-5 -4 -2 -1 -0.5 -0.25 0 0.25 0.5 1 2 4 5]'},'FontSize',10);
g7.set_title('Other options for stat_bin()');
figure('Position',[100 100 800 600]);
g7.draw();
%% Visualize x-y difference with inset histogram using stat_cornerhist()
%Generate sample data
N=200;
x=randn(1,N*4);
y=x+randn(1,N*4)/2;
c=repmat([1 2],1,N*2);
b=repmat([1 2 2 2],1,N);
y(c==1 & b==2)=y(c==1 & b==2)+2;
clear g
g=gramm('x',x,'y',y,'color',c);
g.facet_grid([],b);
g.geom_point();
g.stat_cornerhist('edges',-4:0.1:2,'aspect',0.5);
g.geom_abline();
g.set_title('Visualize x-y with stat_cornerhist()');
figure('Position',[100 100 800 600]);
g.draw();
%Possibility to use axe handles of the inset axes to add elements or change
%properties
plot(g.results.stat_cornerhist(2).child_axe_handle,[-2 -2],[0 50],'k:','LineWidth',2)
%set([g.results.stat_cornerhist.child_axe_handle],'XTick',[])
%% Graphic and normalization options in stat_violin()
clear g
g(1,1)=gramm('x',cars.Origin_Region,'y',cars.Horsepower,'color',cars.Cylinders,'subset',cars.Cylinders~=3 & cars.Cylinders~=5);
g(1,1).set_names('x','Origin','y','Horsepower','color','# Cyl');
g(1,2)=copy(g(1,1));
g(1,3)=copy(g(1,1));
g(2,1)=copy(g(1,1));
g(2,2)=copy(g(1,1));
%Jittered scatter plot
g(1,1).geom_jitter('width',0.6,'height',0,'dodge',0.7);
g(1,1).set_title('jittered data');
g(1,2).stat_violin('normalization','area');
g(1,2).set_title('''normalization'',''area'' (Default)');
g(1,3).stat_violin('normalization','width');
g(1,3).set_title('''normalization'',''width''');
g(2,1).stat_violin('normalization','count','fill','all');
g(2,1).set_title('''normalization'',''count'' , ''fill'',''all''');
g(2,2).stat_violin('half',true,'normalization','count','width',1,'fill','transparent');
g(2,2).set_title('''half'',true , ''fill'',''transparent''');
g(2,3)=gramm('x',cars.Origin_Region,'y',cars.Horsepower,'color',cars.Origin_Region,'subset',cars.Cylinders~=3 & cars.Cylinders~=5);
g(2,3).set_names('x','Origin','y','Horsepower','color','Origin');
g(2,3).stat_violin('normalization','area','dodge',0,'fill','edge');
g(2,3).stat_boxplot('width',0.15);
g(2,3).set_title('with stat_boxplot()');
g(2,3).set_color_options('map','brewer_dark');
g.set_title('Options for stat_violin()');
figure('Position',[100 100 800 600]);
g.draw();
%% Options for geom_swarm()
N=700;
x = floor(rand(N,1)*2);
y = randn(N,1);
y(x==1)=y(x==1)+1;
c = round(rand(N,1)*2);
c=categorical(c);
x=categorical(x);
c(x=="0" & c=="0") = "2";
figure('Position',[100 100 1800 800]);
clear g
g(1,1)=gramm('x',x,'y',y,'color',c);
g(1,2) = copy(g(1,1));
g(1,3) = copy(g(1,1));
g(2,1) = copy(g(1,1));
g(2,2) = copy(g(1,1));
g(2,3) = copy(g(1,1));
g(1,1).geom_swarm('point_size',2);
g(1,1).stat_summary('geom','point','dodge',0.7,'width',0.9)
g(1,1).set_title('default method ''up''');
g(1,2).geom_swarm('point_size',2,'type','fan');
g(1,2).set_title('method ''fan''');
g(1,3).geom_swarm('point_size',2,'type','hex');
g(1,3).set_title('method ''hex''');
g(2,1).geom_swarm('point_size',2,'type','square');
g(2,1).set_title('method ''square''');
g(2,2).geom_swarm('point_size',2,'corral','gutter','alpha',0.5,'dodge',0.8,'width',0.7);
g(2,2).set_title('corral ''gutter'' and alpha 0.3');
g(2,3).geom_swarm('point_size',2,'corral','omit','alpha',0.5,'dodge',0.8,'width',0.7);
g(2,3).set_title('corral ''omit'' and alpha 0.3');
g.set_title('Options for geom_swarm()');
g.draw();
%Make the points marking the group averages more visible
set([g(1,1).results.stat_summary.point_handle],'MarkerFaceColor',[0 0 0])
set([g(1,1).results.stat_summary.point_handle],'Marker','s')
set([g(1,1).results.stat_summary.point_handle],'MarkerSize',8)
%% Options for dodging and spacing graphic elements in |stat_summary()| and |stat_boxplot()|
% |stat_summary()| and |stat_boxplot()|, as well as |stat_bin()|, use a pair of options for
% setting the width of graphical elements (|'width'|) and setting how
% elements of different colors can be dodged to the side to avoid overlap
% (|'dodge'|)
%Create data
x=repmat(1:10,1,100);
catx=repmat({'A' 'B' 'C' 'F' 'E' 'D' 'G' 'H' 'I' 'J'},1,100);
y=randn(1,1000)*3;
c=repmat([1 1 1 1 1 1 1 1 1 1 1 1 2 2 2 2 2 3 2 2 2 1 1 2 2 2 2 3 2 3 2 1 1 2 2 2 2 2 2 2],1,25);
y=2+y+x+c*0.5;
clear g
g(1,1)=gramm('x',catx,'y',y,'color',c);
g(2,1)=copy(g(1));
g(3,1)=copy(g(1));
g(4,1)=copy(g(1));
g(5,1)=copy(g(1));
g(1,1).stat_boxplot();
g(1,1).geom_vline('xintercept',0.5:1:10.5,'style','k-');
g(1,1).set_title('''width'',0.6,''dodge'',0.7 (Default)');
g(2,1).stat_boxplot('width',0.5,'dodge',0);
g(2,1).geom_vline('xintercept',0.5:1:10.5,'style','k-');
g(2,1).set_title('''width'',0.5,''dodge'',0');
g(3,1).stat_boxplot('width',1,'dodge',1);
g(3,1).geom_vline('xintercept',0.5:1:10.5,'style','k-');
g(3,1).set_title('''width'',1,''dodge'',1');
g(4,1).stat_boxplot('width',0.6,'dodge',0.4);
g(4,1).geom_vline('xintercept',0.5:1:10.5,'style','k-');
g(4,1).set_title('''width'',0.6,''dodge'',0.4');
g(5,1).facet_grid([],c);
g(5,1).stat_boxplot('width',0.5,'dodge',0,'notch',true);
g(5,1).set_title('''width'',0.5,''dodge'',0,''notch'',true');
g.set_title('Dodge and spacing options for stat_boxplot()');
figure('Position',[100 100 800 1000]);
g.draw();
%%
% With |stat_summary()|, |'width'| controls the width of bars and error bars.
clear g
g(1,1)=gramm('x',catx,'y',y,'color',c);
g(2,1)=copy(g(1));
g(3,1)=copy(g(1));
g(4,1)=copy(g(1));
g(5,1)=copy(g(1));
g(1,1).stat_summary('geom',{'bar' 'black_errorbar'},'setylim',true);
g(1,1).geom_vline('xintercept',0.5:1:10.5,'style','k-');
g(1,1).set_title('Default dodging with ''geom'',''bar''');
g(2,1).stat_summary('geom',{'bar' 'black_errorbar'},'dodge',0.7,'width',0.7);
g(2,1).set_title('''dodge'',0.7,''width'',0.7');
g(2,1).geom_vline('xintercept',0.5:1:10.5,'style','k-');
g(3,1).stat_summary('geom',{'area'});
g(3,1).set_title('''geom'',''area''');
g(3,1).set_title('No dodging with ''geom'',''area''');
g(4,1).stat_summary('geom',{'point' 'errorbar'},'dodge',0.3,'width',0.5);
g(4,1).set_title('''dodge'',0.3,''width'',0.5');
g(4,1).geom_vline('xintercept',0.5:1:10.5,'style','k-');
g(5,1).facet_grid([],c);
g(5,1).stat_summary('geom',{'bar' 'black_errorbar'},'width',0.5,'dodge',0);
g(5,1).set_title('''width'',0.5,''dodge'',0');
g.set_title('Dodge and width options for stat_summary()');
figure('Position',[100 100 800 1000]);
g.draw();
%% Plotting text or labeling with geom_label()
%Create short version of model names by removing manufacturer
cars.ModelShort=cellfun(@(ma,mo)mo(length(ma)+1:end),cars.Manufacturer,cars.Model,'UniformOutput',false);
figure('Position',[100 100 800 500]);
clear g
%Provide 'label' as data
g=gramm('x',cars.Horsepower,'y',cars.Acceleration,...
'label',cars.ModelShort,'color',cars.Manufacturer,'subset',strcmp(cars.Origin_Region,'Japan'));
%geom_label() takes the same arguments as text().
%'BackgroundColor','EdgeColor' and 'Color' can be set to 'auto'
g.geom_label('VerticalAlignment','middle','HorizontalAlignment','center','BackgroundColor','auto','Color','k');
g.set_limit_extra([0.2 0.2],[0.1 0.1]);
g.set_names('color','Manufacturer','x','Horsepower','y','Acceleration');
g.set_color_options('map','brewer2');
g.draw();
% geom_label works when 3D data is provided
figure('Position',[100 100 800 500]);
g=gramm('x',cars.Horsepower,'y',cars.Acceleration,'z',cars.MPG,...
'label',cars.ModelShort,'color',cars.Manufacturer,'subset',strcmp(cars.Origin_Region,'Japan'));
g.geom_label('VerticalAlignment','middle','HorizontalAlignment','center','BackgroundColor','auto','Color','k');
g.set_limit_extra([0.2 0.2],[0.1 0.1]);
g.set_names('color','Manufacturer','x','Horsepower','y','Acceleration','z','MPG');
g.set_color_options('map','brewer2');
g.draw();
figure('Position',[100 100 800 500]);
clear g
%Compute number of models outside of gramm so that the output can be used
%as label
temp_table=rowfun(@numel,cars,'OutputVariableNames','N','GroupingVariables',{'Origin_Region','Model_Year'},'InputVariables','MPG');
g=gramm('x',temp_table.Model_Year,'y',temp_table.N,'color',temp_table.Origin_Region,'label',temp_table.N);
g.geom_bar('dodge',0.7,'width',0.6);
g.geom_label('color','k','dodge',0.7,'VerticalAlignment','bottom','HorizontalAlignment','center');
g.set_names('color','Origin','x','Year','y','Number of models');
g.draw();
%% Smooth continuous data with stat_smooth()
x=0:0.02:9.8;
y=sin(exp(x-5)/12);
y(x<2)=y(x<2)+randn(1,sum(x<2))/2;
y(x>=2)=y(x>=2)+randn(1,sum(x>=2))/8;
figure('Position',[100 100 800 500]);
clear g
g=gramm('x',x,'y',y);
g.geom_funline('fun',@(x)sin(exp(x-5)/12));
g.geom_vline('xintercept',2)
g.axe_property('XLim',[0 9.8]);
g(1,2)=copy(g(1));
g(1,3)=copy(g(1));
g(2,1)=copy(g(1));
g(2,2)=copy(g(1));
g(2,3)=copy(g(1));
g(1,1).geom_point();
g(1,1).set_title('Raw input');
g(1,2).stat_smooth();
g(1,2).set_title('stat_smooth() default');
g(1,3).stat_smooth('lambda','auto','npoints',500);
g(1,3).set_title('default with ''lambda'',''auto''');
g(2,1).stat_smooth('method','sgolay','lambda',[31 3]);
g(2,1).set_title('''method'',''sgolay''');
g(2,2).stat_smooth('method','moving','lambda',31);
g(2,2).set_title('''method'',''moving''');
g(2,3).stat_smooth('method','loess','lambda',0.1,'setylim',true);
g(2,3).set_title('''method'',''loess'',''setylim'',''true''');
g.set_title('Options for stat_smooth()');
g.draw();
%% Superimposing gramm plots with update(): Using different groups for different stat_ and geom_ methods
% By using the method update() after a first draw() call of a gramm object,
% it is possible to add or remove grouping variables.
% Here in a first gramm plot we make a glm fit of cars Acceleration as a
% function of Horsepower, across all countries and number of cylinders, and
% change the color options so that the fit appears in grey
clear g10
figure('Position',[100 100 600 450]);
g10=gramm('x',cars.Horsepower,'y',cars.Acceleration,'subset',cars.Cylinders~=3 & cars.Cylinders~=5);
g10.set_names('color','# Cylinders','x','Horsepower','y','Acceleration','Column','Origin');
g10.set_color_options('chroma',0,'lightness',30);
g10.stat_glm('geom','area','disp_fit',false);
g10.set_title('Update example'); %Title must be provided before the first draw() call
g10.draw();
snapnow;
%%
% After the first draw() call (optional), we call the update() method by specifying a
% new grouping variable determining colors. We also change the facet_grid()
% options, which will duplicate the fit made earlier across all new facets.
% Last, color options are reinitialized to default values
g10.update('color',cars.Cylinders);
g10.facet_grid([],cars.Origin_Region);
g10.set_color_options();
g10.geom_point();
g10.draw();
%% Superimposing gramm plots with update(): Plotting all the data in the background of facets
%Inspired by https://drsimonj.svbtle.com/plotting-background-data-for-groups-with-ggplot2
load fisheriris.mat
clear g
figure('Position',[100 100 800 600]);
%Create an histogram of all the data in the background (no facet_ is given yet)
g(1,1)=gramm('x',meas(:,2));
g(1,1).set_names('x','Sepal Width','column','');
g(1,1).stat_bin('fill','all'); %histogram
g(1,1).set_color_options('chroma',0,'lightness',75); %We make it light grey
g(1,1).set_title('Overlaid histograms');
%Create a scatter plot of all the data in the background (no facet_ is given yet)
g(2,1)=gramm('x',meas(:,2),'y',meas(:,1));
g(2,1).set_names('x','Sepal Width','column','','y','Sepal Length');
g(2,1).geom_point(); %Scatter plot
g(2,1).set_color_options('chroma',0,'lightness',75); %We make it light grey
g(2,1).set_point_options('base_size',6);
g(2,1).set_title('Overlaid scatter plots');
g.draw(); %Draw the backgrounds
g(1,1).update('color',species); %Add color with update()
g(1,1).facet_grid([],species); %Provide facets
g(1,1).stat_bin('dodge',0); %Histogram (we set dodge to zero as facet_grid makes it useless)
g(1,1).set_color_options(); %Reset to default colors
g(1,1).no_legend();
g(1,1).axe_property('ylim',[-2 30]); %We have to set y scale manually, as the automatic scaling from the first plot was forgotten
g(2,1).update('color',species); %Add color with update()
g(2,1).facet_grid([],species); %Provide facets
g(2,1).geom_point();
g(2,1).set_color_options();
g(2,1).no_legend();
%Set global axe properties
g.axe_property('TickDir','out','XGrid','on','Ygrid','on','GridColor',[0.5 0.5 0.5]);
%Draw the news elements
g.draw();
%% Use custom layouts in gramm, marginal histogram example
load fisheriris.mat
clear g
figure('Position',[100 100 550 550]);