The hardware and bandwidth for this mirror is donated by METANET, the Webhosting and Full Service-Cloud Provider.
If you wish to report a bug, or if you are interested in having us mirror your free-software or open-source project, please feel free to contact us at mirror[@]metanet.ch.
superb
superbPlot()
comes with seven built-in layouts for
plotting your data. However, it is possible to add additional,
custom-made layouts. In this vignette, we present rapidly the existing
layouts, then show how to supplement superb
with your own
layouts.
When calling superbPlot()
, you use the
plotStyle = "layout"
option to indicate which layout you
wish to use. Internally, superbPlot()
is calling a function
whose name is superbPlot."layout"()
. For example, with
plotStyle = "line"
, the plot is actually performed by the
function superbPlot.line()
.
The seven layout available in superbPlot
package are
:
superbPlot.line()
: shows the results as points and
lines,
superbPlot.lineBand()
: Shows the confidence
intervals as a semi-transparent band rather than with bars.
superbPlot.point()
: shows the results as points
only,
superbPlot.bar()
: shows the results using
bars,
superbPlot.pointjitter()
: shows the results with
points, and the raw data with jittered points,
superbPlot.pointjitterviolin()
: also shows violin
plot behind the jitter points, and
superbPlot.pointindividualline()
: show the results
with fat points, and individual results with thin lines,
superbPlot.raincloud()
: Shows the results with
distribution and jitter.
To determine if a certain function is
superbPlot
-compatible, use the following function:
## [1] TRUE
where you put between quote the name of a function. When devising
your own, custom-made function, it is a good thing to check that it is
superbPlot
-compatible.
To get a sense of the currently available layouts, we first generate a dataset composed of randomly generated scores mimicking a 3 \(\times\) 2 design with three degrees of Difficulties (as a between-group factor) and two days of testing (as a within-subject factor). It is believed (and simulated) that all two factors have main effets on the scores.
testdata <- GRD(
RenameDV = "score",
SubjectsPerGroup = 25,
BSFactors = "Difficulty(3)",
WSFactors = "Day(day1, day2)",
Population = list(mean = 65,stddev = 12,rho = 0.5),
Effects = list("Day" = slope(-5), "Difficulty" = slope(3) )
)
head(testdata)
## id Difficulty score.day1 score.day2
## 1 1 1 69.32737 64.58396
## 2 2 1 54.09485 53.13825
## 3 3 1 62.11526 36.56828
## 4 4 1 84.25968 57.77058
## 5 5 1 70.89638 50.41050
## 6 6 1 53.14770 47.44263
For simplicity, we define a function whose arguments are the dataset and the layout:
mp <- function(data, style, ...) {
superb(
cbind(score.day1, score.day2) ~ Difficulty,
data,
WSFactors = "Day(2)",
adjustments = list(purpose="difference", decorrelation="CA"),
plotStyle = style,
...
)+labs(title = paste("Layout is ''",style,"''",sep=""))
}
Lets compute the plots will the first six built-in layouts and show them
p1 <- mp(testdata, "bar")
p2 <- mp(testdata, "point")
p3 <- mp(testdata, "line")
p4 <- mp(testdata, "pointjitter" )
p5 <- mp(testdata, "pointjitterviolin")
p6 <- mp(testdata, "pointindividualline")
library(gridExtra)
grid.arrange(p1,p2,p3,p4,p5,p6,ncol=2)
A cool format, a raincloud
plot (Allen et al., 2021), is better seen with
coordinates flipped over:
Finally, the following shows the latest layout, a box plot, better for showing median and confidence interval of the median, obtained with
For more controls, you can manually set the colors, the fills and/or the shapes, as done here in a list:
ornate = list(
scale_colour_manual( name = "Difference",
labels = c("Easy", "Hard", "Unthinkable"),
values = c("blue", "black", "purple")) ,
scale_fill_manual( name = "Difference",
labels = c("Easy", "Hard", "Unthinkable"),
values = c("blue", "black", "purple")) ,
scale_shape_manual( name = "Difference",
labels = c("Easy", "Hard", "Unthinkable") ,
values = c(0, 10, 13)) ,
theme_bw(base_size = 9) ,
labs(x = "Days of test", y = "Score in points" ),
scale_x_discrete(labels=c("1" = "Former day", "2" = "Latter day"))
)
library(gridExtra)
grid.arrange(
p1+ornate, p2+ornate, p3+ornate,
p4+ornate, p5+ornate, p6+ornate,
ncol=2)
These are just a few examples. However, if these layouts do not fit
yours needs, it is possible to devise a custom-made layout and inform
superbPlot
to use it. To that end, see the instructions
below.
In a nutshell, the purpose of superbPlot()
is to
compile the summary information (location of the summary statistic, upper width and lower width of the interval) and that, for each level of the factors;
applies all the adjustments needed in producing the summary;
and finally, calls a plot function accepting pre-defined arguments
In devising your own plot function, it is important that (i) the
function name begins with superbPlot.
; (ii) the function
accept very specific arguments with very precise names.
Here is the header for a function corresponding to a plot style
called, say, foo (plotStyle = "foo"
):
superbPlot.foo <- function(
summarydata,
xfactor,
groupingfactor,
addfactors,
rawdata
# any optional argument you wish
) {
plot <- ggplot() ## ggplot instructions...
return(plot)
}
In what follow, it is assumed that one factor is placed on the
horizontal axis (xfactor
), another one is used to group the
point (groupingfactor
), and up to two additional factors
will results in columns and rows of panels (addfactors
; of
course, in devising your own template, you may use different placement).
superbPlot()
is restricted to a maximum of four
factors.
The arguments are:
summarydata
: this data frame will contain the column
center
indicating the statistic’s value,
lowerwidth
and upperwidth
indicating how many
units below and above center
the error bar extends. The
data frame will also have columns for all the factors, and there will be
as many lines as there are combinations of factors.
xfactor
is the factor to put on the horizontal
axis;
groupingfactor
is the factor used to create groups
of points;
addfactors
are up to two additional factors to
create the rows and columns of panels. addfactors
is
formatted for facetting (e.g., for factors “A” and “B”,
addfactors
would be “A~B”);
rawdata
: this data.frame contains the raw data with
factors being transformed as.factor
and the dependent
column being renamed DV
. When the data are in wide format,
rawdata
is reshaped to long format.
{optional arguments}
can be used. They must be named
here; when calling superbPlot()
, any argument whose name
match your optional argument will be transmitted to your custom-made
function.
What follow is a simple example that will design a template that we
will call simple
. This layout will display the descriptive
statistics and error bars. Everything will be black and white (no color
instruction) and superimposed (no grouping instruction).
The result will be:
To make this plot, we design a function
superbPlot.simple
as:
superbPlot.simple <- function(
summarydata, xfactor, groupingfactor, addfactors, rawdata
) {
plot <- ggplot(
data = summarydata,
mapping = aes( x = !!sym(xfactor), y = center, group = !!sym(groupingfactor) )
) +
geom_point( ) +
geom_errorbar( mapping = aes(ymin = center + lowerwidth,
ymax = center + upperwidth) )+
facet_grid( addfactors )
return(plot)
}
The first instruction, ggplot
defines the source data to
be summarydata
with horizontal axis being in the string
xfactor
(the piece of instructions !!sym( )
converts the string into a variable). The position of the descriptive
statistics is automatically computed and stored in a column called
center
.
The second instruction put points for each center
, and
the third instruction places error bars. In that case, the
ymin
and ymax
information are contained in
center+lowerwidth
and center+upperwidth
where
lowerwidth
and upperwidth
are automaticall
computed and stored in the summarydata
dataframe.
The last instructions generates distinct panels for each level of the remaining factors.
You can check that this function is
superbPlot
-compatible with:
## [1] TRUE
If TRUE
, then we are ready to use this layout, here with
the demo dataset TMB1964r
whose result was shown above in
Figure 3:
The above simple
layout does not accept optional
arguments. To integrate optional arguments, one method is to insert
graphic directives inside the layers, e.g., inside
geom_point
.
A convenient method is with do.call
and
modifyList
, for example:
A full example it therefore
superbPlot.simpleWithOptions <- function(
summarydata, xfactor, groupingfactor, addfactors, rawdata,
myownpointParams = list(), ## will be used to add the optional arguments to the function
myownebParams = list() ## will be used to add the optional arguments to the function
) {
plot <- ggplot(
data = summarydata,
mapping = aes( x = !!sym(xfactor), y = center, group=Condition)
) +
do.call( geom_point, modifyList(
list( color ="black" ),
myownpointParams
)) +
do.call( geom_errorbar, modifyList(
list( mapping = aes(ymin = center + lowerwidth,
ymax = center + upperwidth) ),
myownebParams
)) +
facet_grid( addfactors )
return(plot)
}
superb:::is.superbPlot.function("superbPlot.simpleWithOptions")
## [1] TRUE
superb(
crange(T1,T7) ~ Condition,
TMB1964r,
WSFactors = "T(7)",
plotStyle = "simpleWithOptions",
## here goes the optional arguments
myownpointParams = list(size=1, color="purple", position = position_dodge(width = 0.3) ),
myownebParams = list(linewidth=1, color="purple", position = position_dodge(width = 0.3) )
)
In that example, the same parameters are sent to
geom_point
and to geom_errorbar
. It is left as
an exercice to the reader to use two distinct sets of optional
parameters, one for the points, the other for the error bars.
It is sometimes useful to extract variables out of the function when
debugging the code. A useful function is to use runDebug()
.
This function (shipped with suberb
) will display text and
transfer any variables you want into the global environment.
options(superb.feedback = 'all')
runDebug( 'where are we?', "Text to show when we get there",
c("variable1", "variable2", "etc"),
list( "var1InTheFct", "var2InTheFct", "varetcInTheFct")
)
## ==> Text to show when we get there <==
## variables dumped in: variable1, variable2, etc
For example, the following will get the dataframes:
superbPlot.empty <- function(
summarydata, xfactor, groupingfactor, addfactors, rawdata
) {
runDebug( 'inempty', "Dumping the two dataframes",
c("summary","raw"), list(summarydata, rawdata))
plot <- ggplot() # an empty plot
return(plot)
}
options(superb.feedback = 'inempty') ## turn on feedback when reaching 'inempty'
superb(
crange(T1,T7) ~ Condition,
TMB1964r,
WSFactors = "T(7)",
plotStyle = "empty"
)
## ==> Dumping the two dataframes <==
## variables dumped in: summary, raw
You see Dumping the two dataframes
followed by
summary
and raw
. These two variables are now
in the global environment and you can manipulate them. You can also use
them in testing your plotting functions, for example
In what follow, we create a toy example where the raw data will be shown with smileys. Note that this example may not work in Rstudio (see “limitation” on emojifont page )
We first need the emojifont
library
Then we define a "smiley"
layout where the emojis are
shown with geom_text
layer:
superbPlot.smiley <- function( summarydata, xfactor, groupingfactor, addfactors, rawdata ) {
# the early part bears on summary data with variable "center"
plot <- ggplot(
data = summarydata,
mapping = aes(
x = !!sym(xfactor),
y = center,
fill = !!sym(groupingfactor),
shape = !!sym(groupingfactor),
colour = !!sym(groupingfactor) )
) +
geom_point(position = position_dodge(width = .95)) +
geom_errorbar( width = .6, position = position_dodge(.95),
mapping = aes(ymin = center + lowerwidth, ymax = center + upperwidth)
)+
# this part bears on the rawdata only with variable "DV"
geom_text(data = rawdata,
position = position_jitter(0.5),
family = "EmojiOne",
label = emoji("smile"),
size = 6,
mapping = aes(x = !!sym(xfactor), y = DV, group = !!sym(groupingfactor) )
) +
facet_grid( addfactors )
return(plot)
}
We check that it is a superbPlot
-compatible
function:
## [1] TRUE
It is all we need! This layout can be inserted in a
superbPlot
call:
These binaries (installable software) and packages are in development.
They may not be fully stable and should be used with caution. We make no claims about them.