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With the tmap package, thematic maps can be generated with great
flexibility. The syntax for creating plots is similar to that of
ggplot2
, but tailored to maps. This vignette is for those
who want to get started with tmap within a couple of minutes. A more
detailed description of tmap can be found in an article
published in the Journal of Statistical Software (JSS). However, that article
describes tmap version 1.11-2, which is out-of-date. Some major changes
have been made since then, which are described in vignette("tmap-changes")
.
For more context on R’s geographic capabilities we recommend the
online version of the book Geocomputation with R. The Making maps with R chapter of
the book provides many more context and abundant code examples of map
making with tmap
and other packages. Other good resources
are the vignettes of the sf
package.
A good place to start is to create a map of the world. After installing tmap, the following lines of code should create the map shown below:
The object World
is a spatial object of class
sf
from the sf package; it is a
data.frame
with a special column that contains a geometry
for each row, in this case polygons. In order to plot it in tmap, you
first need to specify it with tm_shape
. Layers can be added
with the +
operator, in this case tm_polygons
.
There are many layer functions in tmap, which can easily be found in the
documentation by their tm_
prefix. See also
?'tmap-element'
.
Each map can be plotted as a static image or viewed interactively
using "plot"
and "view"
modes, respectively.
The mode can be set with the function tmap_mode
, and
toggling between the modes can be done with the ‘switch’
ttm()
(which stands for toggle thematic map.
A shape is a spatial object (with a class from sf
,
sp
, stars
, or raster
). Multiple
shapes and also multiple layers per shape can be plotted:
data(World, metro, rivers, land)
tmap_mode("plot")
## tmap mode set to plotting
tm_shape(land) +
tm_raster("elevation", palette = terrain.colors(10)) +
tm_shape(World) +
tm_borders("white", lwd = .5) +
tm_text("iso_a3", size = "AREA") +
tm_shape(metro) +
tm_symbols(col = "red", size = "pop2020", scale = .5) +
tm_legend(show = FALSE)
## old-style crs object detected; please recreate object with a recent sf::st_crs()
## old-style crs object detected; please recreate object with a recent sf::st_crs()
## old-style crs object detected; please recreate object with a recent sf::st_crs()
Facets can be created in three ways:
tm_polygons
:tmap_mode("view")
tm_shape(World) +
tm_polygons(c("HPI", "economy")) +
tm_facets(sync = TRUE, ncol = 2)
by
argument of
tm_facets
:tmap_mode("plot")
## tmap mode set to plotting
data(NLD_muni)
NLD_muni$perc_men <- NLD_muni$pop_men / NLD_muni$population * 100
tm_shape(NLD_muni) +
tm_polygons("perc_men", palette = "RdYlBu") +
tm_facets(by = "province")
## old-style crs object detected; please recreate object with a recent sf::st_crs()
## old-style crs object detected; please recreate object with a recent sf::st_crs()
## old-style crs object detected; please recreate object with a recent sf::st_crs()
## old-style crs object detected; please recreate object with a recent sf::st_crs()
## old-style crs object detected; please recreate object with a recent sf::st_crs()
tmap_arrange
function:tmap_mode("plot")
## tmap mode set to plotting
data(NLD_muni)
tm1 <- tm_shape(NLD_muni) + tm_polygons("population", convert2density = TRUE)
tm2 <- tm_shape(NLD_muni) + tm_bubbles(size = "population")
tmap_arrange(tm1, tm2)
## old-style crs object detected; please recreate object with a recent sf::st_crs()
## old-style crs object detected; please recreate object with a recent sf::st_crs()
## old-style crs object detected; please recreate object with a recent sf::st_crs()
## old-style crs object detected; please recreate object with a recent sf::st_crs()
## old-style crs object detected; please recreate object with a recent sf::st_crs()
## old-style crs object detected; please recreate object with a recent sf::st_crs()
## old-style crs object detected; please recreate object with a recent sf::st_crs()
## old-style crs object detected; please recreate object with a recent sf::st_crs()
## old-style crs object detected; please recreate object with a recent sf::st_crs()
## old-style crs object detected; please recreate object with a recent sf::st_crs()
## old-style crs object detected; please recreate object with a recent sf::st_crs()
## old-style crs object detected; please recreate object with a recent sf::st_crs()
## old-style crs object detected; please recreate object with a recent sf::st_crs()
## old-style crs object detected; please recreate object with a recent sf::st_crs()
## old-style crs object detected; please recreate object with a recent sf::st_crs()
## old-style crs object detected; please recreate object with a recent sf::st_crs()
## old-style crs object detected; please recreate object with a recent sf::st_crs()
## old-style crs object detected; please recreate object with a recent sf::st_crs()
## old-style crs object detected; please recreate object with a recent sf::st_crs()
## old-style crs object detected; please recreate object with a recent sf::st_crs()
## Legend labels were too wide. Therefore, legend.text.size has been set to 0.27. Increase legend.width (argument of tm_layout) to make the legend wider and therefore the labels larger.
## The legend is too narrow to place all symbol sizes.
Tiled basemaps can be added with the layer function
tm_basemap
. Semi-transparent overlay maps (for example
annotation labels) can be added with tm_tiles
.
tmap_mode("view")
tm_basemap("Stamen.Watercolor") +
tm_shape(metro) + tm_bubbles(size = "pop2020", col = "red") +
tm_tiles("Stamen.TonerLabels")
See a preview
of the available tilemaps. This list is also accessible in R:
leaflet::providers
.
The functions tm_layout
and tm_view
are
used to specify the map layout and the interactive aspects respectively.
These functions can be used in the same way as the layer functions,
e.g.
tmap_mode("plot")
## tmap mode set to plotting
tm_shape(World) +
tm_polygons("HPI") +
tm_layout(bg.color = "skyblue", inner.margins = c(0, .02, .02, .02))
These options, as well as a couple of others, can also be set within
with tmap_options
, which works in the same way as the base
R function options
. The main advantage is that these
options are set globally, so they do not have to be specified in each
map, for the duration of the session.
tmap_options(bg.color = "black", legend.text.color = "white")
tm_shape(World) +
tm_polygons("HPI", legend.title = "Happy Planet Index")
A style is a certain configuration of the tmap options.
tmap_style("classic")
## tmap style set to "classic"
## other available styles are: "white", "gray", "natural", "cobalt", "col_blind", "albatross", "beaver", "bw", "watercolor"
tm_shape(World) +
tm_polygons("HPI", legend.title = "Happy Planet Index")
# see what options have been changed
tmap_options_diff()
## current tmap options (style "classic") that are different from default tmap options (style "white"):
## $sepia.intensity
## [1] 0.7
##
## $frame.double.line
## [1] TRUE
##
## $fontfamily
## [1] "serif"
##
## $compass.type
## [1] "rose"
##
## $basemaps
## [1] "Esri.WorldTopoMap"
##
## $basemaps.alpha
## [1] 0.5
# reset the options to the default values
tmap_options_reset()
## tmap options successfully reset
New styles can be created; see ?tmap_options
.
It is possible to use tmap in shiny:
# in UI part:
tmapOutput("my_tmap")
# in server part
output$my_tmap = renderTmap({
tm_shape(World) + tm_polygons("HPI", legend.title = "Happy Planet Index")
})
See ?renderTmap
for a working example.
Maps can also be made with one function call. This function is
qtm
:
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.