A first example
We will start by creating a set of circles of various sizes and then
using the circleRepelLayout function to find a
non-overlapping arrangement which we can display with ggplot.
First we create a set of random circles, positioned within the
central portion of a bounding square, with smaller circles being more
common than larger ones. We will express circle size as area. This is
the default for circleRepelLayout but you can also express
size as radius and specify `sizetype = “radius” when calling the
function.
set.seed(42)
ncircles <- 200
limits <- c(-40, 40)
inset <- diff(limits) / 3
maxarea <- 40
areas <- rbeta(ncircles, 1, 5) * maxarea
Next, we use the circleRepelLayout function to try to
find a non-overlapping arragement, allowing the circles to occupy any
part of the bounding square. The returned value is a list with elements
for the layout and the number of iterations performed.
library(packcircles)
res <- circleRepelLayout(areas, xlim = limits, ylim = limits)
cat(res$niter, "iterations performed")
## 375 iterations performed
The layout is returned as a data frame with circle centre coordinates
and radii.
## x y radius
## 1 13.1147122 -0.6669234 1.1308380
## 2 0.4995586 -18.3833175 0.9218804
## 3 -1.6417293 8.6140819 1.0971732
## 4 4.2994181 -21.5244595 1.5616752
## 5 -3.6841895 -1.2990119 0.4189622
## 6 14.8024399 -9.1574151 1.5501321
We convert this to a data set of circle vertices, suitable for
display with ggplot. The number of vertices can be controlled with the
npoints argument but we use the default.
The resulting data set has an integer id field which
corresponds to the position or row of the circle in the original data
passed to circleRepelLayout.
dat.gg <- circleLayoutVertices(res$layout, sizetype = "radius")
head(dat.gg)
## x y id
## 1 14.24555 -0.6669234 1
## 2 14.21002 -0.3856954 1
## 3 14.10567 -0.1221380 1
## 4 13.93906 0.1071885 1
## 5 13.72065 0.2878748 1
## 6 13.46416 0.4085675 1
And now we can draw the layout.
library(ggplot2)
t <- theme_bw() +
theme(panel.grid = element_blank(),
axis.text=element_blank(),
axis.ticks=element_blank(),
axis.title=element_blank())
theme_set(t)
ggplot(data = dat.gg, aes(x, y, group = id)) +
geom_polygon(colour="brown", fill="burlywood", alpha=0.3) +
coord_equal(xlim=limits, ylim=limits)
Specifying initial circle positions
In the previous example, where we passed a vector of circle sizes to
circleRepelLayout, the function randomly assigned starting
positions to the circles by placing them close to the centre of the
bounding area. Alternatively, we can specify the initial positions
beforehand. To illustrate this, we will initially position all of the
circles near one corner of the bounding area.
dat.init <- data.frame(
x = runif(ncircles, limits[1], limits[2]),
y = runif(ncircles, limits[1], limits[2]) / 4.0,
area = areas
)
res <- circleRepelLayout(dat.init, xlim = limits, ylim = limits,
xysizecols = 1:3)
cat(res$niter, "iterations performed")
## 184 iterations performed
Next we display the initial and final layouts with ggplot. Notice
that in our initial layout we expressed circle sizes as areas so we need
to specify that when calling the circleLayoutVertices
function, otherwise it assumes sizes are radii.
# Get vertex data for the initial layout where sizes are areas
dat.gg.initial <- circleLayoutVertices(dat.init, sizetype = "area")
# Get vertex data for the layout returned by the function where
# sizes are radii
dat.gg.final <- circleLayoutVertices(res$layout)
dat.gg <- rbind(
cbind(dat.gg.initial, set=1),
cbind(dat.gg.final, set=2)
)
ggplot(data = dat.gg, aes(x, y, group = id)) +
geom_polygon(colour="brown", fill="burlywood", alpha=0.3) +
coord_equal(xlim=limits, ylim=limits) +
facet_wrap(~ set,
labeller = as_labeller(c(`1` = "Initial layout",
`2` = "Final layout")))
Moving and fixed circles
The circleRepelLayout function accepts an optional
weights argument to give extra control over the movement of
circles at each iteration of the layout algorithm. The argument takes a
numeric vector with values in the range 0-1 inclusive (any values
outside this range will be clamped to 0 or 1). A weight of 0 prevents a
circle from moving at all while a weight of 1 allows full movement.
To illustrate this, we will choose a few circles from the data set
used ealier, make them larger and fix their position by setting their
weights to 0.0.
# choose several arbitrary circles and make them the larger
# than the others
largest.ids <- sample(1:ncircles, 10)
dat.init$area[largest.ids] <- 2 * maxarea
# re-generate the vertex data for the initial circles, adding a column
# to indicate if a circle is fixed (the largest) or free
dat.gg.initial <- circleLayoutVertices(dat.init, sizetype = "area")
dat.gg.initial$state <- ifelse(dat.gg.initial$id %in% largest.ids, "fixed", "free")
# now re-run the layout algorithm with a weights vector to fix the position
# of the largest circle
wts <- rep(1.0, nrow(dat.init))
wts[ largest.ids ] <- 0.0
res <- circleRepelLayout(dat.init, xlim = limits, ylim = limits, weights=wts)
dat.gg.final <- circleLayoutVertices(res$layout)
dat.gg.final$state <- ifelse(dat.gg.final$id %in% largest.ids, "fixed", "free")
dat.gg <- rbind(
cbind(dat.gg.initial, set = 1),
cbind(dat.gg.final, set = 2)
)
ggplot(data = dat.gg, aes(x, y, group=id, fill=state)) +
geom_polygon(colour="brown1", show.legend = FALSE) +
scale_fill_manual(breaks = c("fixed", "free"), values=c("brown4", NA)) +
coord_equal(xlim=limits, ylim=limits) +
facet_wrap(~ set,
labeller = as_labeller(c(`1` = "Initial layout",
`2` = "Final layout")))
Notice that fixed circles that were overlapping in the initial layout
are still overlapping in the final layout. Setting their weights to 0.0
resulted in them being ignored by circleRepelLayout.