If you’ve ever made animated data visualisations you’ll know that
arbitrary polygons and lines requires special considerations if the
animation is to be smooth and believable. transformr
is able to remove
all of these worries by expanding
tweenr
to understand spatial
data, and thus lets you focus on defining your animation steps.
transformr
takes care of matching shapes between states, cutting some
in bits if the number doesn’t match between the states, and ensures that
each pair of matched shapes contains the same number of anchor points
and that these are paired up so as to avoid rotation and inversion
during animation.
transformr
supports both polygons (with holes), and paths either
encoded as simple x/y data.frames or as simpel features using the
sf
package.
You can install transformr from CRAN using
install.packages('transformr')
or grab the development version from
github with:
# install.packages("devtools")
devtools::install_github("thomasp85/transformr")
These are simple, contrieved examples showing how the API works. It scales simply to more complicated shapes.
A polygon is simply a data.frame with an x
and y
column, where each
row demarcates an anchor point for the polygon. The polygon is not in
closed form, that is, the first point is not repeated in the end. If
more polygons are wanted you can provide an additional column that
indicate the polygon membership of a column (quite like
ggplot2::geom_polygon()
expects an x
, y
, and group
variable). If
holed polygons are needed, holes should follow the main polygon and be
separated with an NA
row in the x
and y
column.
library(transformr)
library(tweenr)
library(ggplot2)
polyplot <- function(data) {
p <- ggplot(data) +
geom_polygon(aes(x, y, group = id, fill = col)) +
scale_fill_identity() +
coord_fixed(xlim = c(-1.5, 1.5), ylim = c(-1.5, 1.5))
plot(p)
}
star <- poly_star()
star$col <- 'steelblue'
circles <- poly_circles()
circles$col <- c('forestgreen', 'firebrick', 'goldenrod')[circles$id]
animation <- tween_polygon(star, circles, 'cubic-in-out', 40, id) %>%
keep_state(10)
ani <- lapply(split(animation, animation$.frame), polyplot)
By default the polygons are matched up based on their id. In the above
example there’s a lack of polygons in the start-state, so these have to
appear somehow. This is governed by the enter
function, which by
default is NULL
meaning new polygons just appear at the end of the
animation. We can change this to get a nicer result:
# Make new polygons appear 2 units below their end position
from_below <- function(data) {
data$y <- data$y - 2
data
}
animation <- tween_polygon(star, circles, 'cubic-in-out', 40, id, enter = from_below) %>%
keep_state(10)
ani <- lapply(split(animation, animation$.frame), polyplot)
Similar to the enter
function it is possible to supply an exit
function when the start state has more polygons than the end state.
These functions get a single polygon with the state it was/will be, that
can then be manipulated at will, as long as the same number of rows and
columns are returned.
The
enter
andexit
functions have slightly different semantics here than intweenr::tween_state()
where it gets all entering/exiting rows in one go, and not one-by-one
Our last option is to not match the polygons up, but simply say “make
everything in the first state, into everything in the last state…
somehow”. This involves cutting up polygons in the state with fewest
polygons and match polygons by minimizing the distance and area
difference between pairs. All of this is controlled by setting
match = FALSE
in tween_polygon()
, and transformr
will then do its
magic:
animation <- tween_polygon(star, circles, 'cubic-in-out', 40, id, match = FALSE) %>%
keep_state(10)
ani <- lapply(split(animation, animation$.frame), polyplot)
Paths are a lot like polygons, except that they don’t wrap-around.
Still, slight differences in how they are tweened exists. Chief among
these are that the winding order are not changed to minimize the
travel-distance, because paths often have an implicit direction and this
should not be tampered with. Further, when automatic matching paths
(that is, match = FALSE
), paths are matched to minimize the difference
in length as well as the pair distance. The same interpretation of the
enter
, exit
, and match
arguments remain, which can be seen in the
two examples below:
pathplot <- function(data) {
p <- ggplot(data) +
geom_path(aes(x, y, group = id)) +
coord_fixed(xlim = c(-1.5, 1.5), ylim = c(-1.5, 1.5))
plot(p)
}
spiral <- path_spiral()
waves <- path_waves()
animation <- tween_path(spiral, waves, 'cubic-in-out', 40, id, enter = from_below) %>%
keep_state(10)
ani <- lapply(split(animation, animation$.frame), pathplot)
animation <- tween_path(spiral, waves, 'cubic-in-out', 40, id, match = FALSE) %>%
keep_state(10)
ani <- lapply(split(animation, animation$.frame), pathplot)
The sf
package provides an implemention of simple features which are a
way to encode any type of geometry in defined classes and operate on
them. transformr
supports (multi)point, (multi)linestring, and
(multi)polygon geometries which acount for most of the use cases. When
using the tween_sf()
function any sfc
column will be tweened by
itself, while the rest will be tweened by tweenr::tween_state()
. For
any multi type, the tweening progress as if match = FALSE
in
tween_polygon()
and tween_path()
, that is polygons/paths are cut and
matched to even out the two states. For multipoint the most central
points are replicated to ensure the same number of points in each state.
One nice thing about sf
is that you can encode different geometry
types in the same data.frame and plot it all at once:
sfplot <- function(data) {
p <- ggplot(data) +
geom_sf(aes(colour = col, geometry = geometry)) +
coord_sf(datum = NA) + # remove graticule
scale_colour_identity()
plot(p)
}
star_hole <- poly_star_hole(st = TRUE)
circles <- poly_circles(st = TRUE)
spiral <- path_spiral(st = TRUE)
waves <- path_waves(st = TRUE)
random <- point_random(st = TRUE)
grid <- point_grid(st = TRUE)
df1 <- data.frame(
geo = sf::st_sfc(star_hole, spiral, random),
col = c('steelblue', 'forestgreen', 'goldenrod')
)
df2 <- data.frame(
geo = sf::st_sfc(circles, waves, grid),
col = c('goldenrod', 'firebrick', 'steelblue')
)
animation <- tween_sf(df1, df2, 'cubic-in-out', 40) %>%
keep_state(10)
ani <- lapply(split(animation, animation$.frame), sfplot)