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Use the color scales in this package to make plots that are pretty, better represent your data, easier to read by those with colorblindness, and print well in gray scale.
Install viridis like any R package:
install.packages("viridis")
library(viridis)
For base plots, use the viridis()
function to generate a
palette:
x <- y <- seq(-8*pi, 8*pi, len = 40)
r <- sqrt(outer(x^2, y^2, "+"))
filled.contour(cos(r^2)*exp(-r/(2*pi)),
axes=FALSE,
color.palette=viridis,
asp=1)
For ggplot, use scale_color_viridis()
and
scale_fill_viridis()
:
library(ggplot2)
ggplot(data.frame(x = rnorm(10000), y = rnorm(10000)), aes(x = x, y = y)) +
geom_hex() + coord_fixed() +
scale_fill_viridis() + theme_bw()
viridis
,
and its companion package viridisLite
provide a series of color maps that are designed to improve graph
readability for readers with common forms of color blindness and/or
color vision deficiency. The color maps are also perceptually-uniform,
both in regular form and also when converted to black-and-white for
printing.
These color maps are designed to be:
viridisLite
provides the base functions for generating
the color maps in base R
. The package is meant to be as
lightweight and dependency-free as possible for maximum compatibility
with all the R
ecosystem. viridis
provides additional functionalities, in particular bindings for
ggplot2
.
The package contains eight color scales: “viridis”, the primary choice, and five alternatives with similar properties - “magma”, “plasma”, “inferno”, “civids”, “mako”, and “rocket” -, and a rainbow color map - “turbo”.
The color maps viridis
, magma
,
inferno
, and plasma
were created by Stéfan van
der Walt (@stefanv) and Nathaniel Smith (@njsmith). If you want to know more about
the science behind the creation of these color maps, you can watch this
presentation of
viridis
by their authors at SciPy 2015.
The color map cividis
is a corrected version of
‘viridis’, developed by Jamie R. Nuñez, Christopher R. Anderton, and
Ryan S. Renslow, and originally ported to R
by Marco
Sciaini (@msciain). More info about
cividis
can be found in this
paper.
The color maps mako
and rocket
were
originally created for the Seaborn
statistical data
visualization package for Python. More info about mako
and
rocket
can be found on the Seaborn
website.
The color map turbo
was developed by Anton Mikhailov to
address the shortcomings of the Jet rainbow color map such as false
detail, banding and color blindness ambiguity. More infor about
turbo
can be found here.
Let’s compare the viridis and magma scales against these other commonly used sequential color palettes in R:
rainbow.colors
,
heat.colors
, cm.colors
It is immediately clear that the “rainbow” palette is not perceptually uniform; there are several “kinks” where the apparent color changes quickly over a short range of values. This is also true, though less so, for the “heat” colors. The other scales are more perceptually uniform, but “viridis” stands out for its large perceptual range. It makes as much use of the available color space as possible while maintaining uniformity.
Now, let’s compare these as they might appear under various forms of colorblindness, which can be simulated using the dichromat package:
We can see that in these cases, “rainbow” is quite problematic - it is not perceptually consistent across its range. “Heat” washes out at bright colors, as do the brewer scales to a lesser extent. The ggplot scale does not wash out, but it has a low perceptual range - there’s not much contrast between low and high values. The “viridis” and “magma” scales do better - they cover a wide perceptual range in brightness in brightness and blue-yellow, and do not rely as much on red-green contrast. They do less well under tritanopia (blue-blindness), but this is an extrememly rare form of colorblindness.
The viridis()
function produces the viridis
color scale. You can choose the other color scale options using the
option
parameter or the convenience functions
magma()
, plasma()
, inferno()
,
cividis()
, mako()
,
rocket
(), and
turbo()`.
Here the inferno()
scale is used for a raster of U.S.
max temperature:
library(terra)
library(httr)
par(mfrow=c(1,1), mar=rep(0.5, 4))
temp_raster <- "http://ftp.cpc.ncep.noaa.gov/GIS/GRADS_GIS/GeoTIFF/TEMP/us_tmax/us.tmax_nohads_ll_20150219_float.tif"
try(GET(temp_raster,
write_disk("us.tmax_nohads_ll_20150219_float.tif")), silent=TRUE)
us <- rast("us.tmax_nohads_ll_20150219_float.tif")
us <- project(us, y="+proj=aea +lat_1=29.5 +lat_2=45.5 +lat_0=37.5 +lon_0=-96 +x_0=0 +y_0=0 +ellps=GRS80 +datum=NAD83 +units=m +no_defs")
image(us, col=inferno(256), asp=1, axes=FALSE, xaxs="i", xaxt='n', yaxt='n', ann=FALSE)
The package also contains color scale functions for
ggplot plots: scale_color_viridis()
and
scale_fill_viridis()
. As with viridis()
, you
can use the other scales with the option
argument in the
ggplot
scales.
Here the “magma” scale is used for a cloropleth map of U.S.
unemployment:
##
## Attaching package: 'maps'
## The following object is masked from 'package:viridis':
##
## unemp
library(mapproj)
data(unemp, package = "viridis")
county_df <- map_data("county", projection = "albers", parameters = c(39, 45))
names(county_df) <- c("long", "lat", "group", "order", "state_name", "county")
county_df$state <- state.abb[match(county_df$state_name, tolower(state.name))]
county_df$state_name <- NULL
state_df <- map_data("state", projection = "albers", parameters = c(39, 45))
choropleth <- merge(county_df, unemp, by = c("state", "county"))
choropleth <- choropleth[order(choropleth$order), ]
ggplot(choropleth, aes(long, lat, group = group)) +
geom_polygon(aes(fill = rate), colour = alpha("white", 1 / 2), linewidth = 0.2) +
geom_polygon(data = state_df, colour = "white", fill = NA) +
coord_fixed() +
theme_minimal() +
ggtitle("US unemployment rate by county") +
theme(axis.line = element_blank(), axis.text = element_blank(),
axis.ticks = element_blank(), axis.title = element_blank()) +
scale_fill_viridis(option="magma")
The ggplot functions also can be used for discrete scales with the
argument discrete=TRUE
.
Here are some examples of viridis being used in the wild:
James Curley uses viridis for matrix plots (Code):
Christopher Moore created these contour plots of potential in a dynamic plankton-consumer model:
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.