Installation
geofi
can be installed from CRAN using
# install from CRAN
install.packages("geofi")
# Install development version from GitHub
remotes::install_github("ropengov/geofi")
This vignettes gives an overview of different options for creating
maps in R using the data from geofi
-package. Vignette is
divided in three sections: R-packages for static maps,
static maps using ggplot2 and interactive maps. But we
begin with the datasets we want to plot.
If you want more detailed explanation of how to plot
sf
-objects take a look at vignette 5. Plotting
Simple Features.
Lets start with latest municipality division from
get_municipalities()
with is a POLYGON data and
with POINT data of municipality_central_localities
that is shipped with the package.
library(geofi)
polygon <- get_municipalities(year = 2021, scale = 4500)
point <- geofi::municipality_central_localities
# municipality code into integer
point$municipality_code <- as.integer(point$kuntatunnus)
They both come in same CRS EPSG:3067
and can be plotted
together without any further manipulation.
There are two main technologies for creating static graphics in R: base and ggplot2. Both can be used to plot spatial data ie. to create maps. In addition, tmap : thematic maps in R is a great tool if you want to dig deeper into cartography in R.
base
library(sf)
plot(st_geometry(polygon["municipality_code"]))
plot(polygon["municipality_code"], add = TRUE, border="white")
plot(st_geometry(point["municipality_code"]), add = TRUE, color = "black")
ggplot2
library(ggplot2)
ggplot() +
geom_sf(data = polygon, aes(fill = municipality_code)) +
geom_sf(data = point)
tmap
tmap
is a
versatile library for creating static thematic maps in R. It supports
sf
-class objects and is fully compatible with geospatial
data available through geofi
.
As I am only fluent in using ggplot2
the the more
complex examples are using ggplot2
-package.
ggplot2
-packages has three sf
-class
spesific functions: geom_sf
plotting for points, lines and
polygons, and geom_sf_text
and geom_sf_label
for labeling the maps. In the following examples we are using the
Uusimaa region in Southern Finland.
library(dplyr)
polygon_uusimaa <- polygon %>% filter(maakunta_name_fi %in% "Uusimaa")
point_uusimaa <- point %>% filter(municipality_code %in% polygon_uusimaa$municipality_code)
ggplot() +
theme_light() +
geom_sf(data = polygon_uusimaa, alpha = .3) +
geom_sf(data = point_uusimaa) +
geom_sf_text(data = point_uusimaa, aes(label = teksti))
geom_sf_label
or geom_sf_text
cannot
control the overlapping of labels which is a common issue when mapping
objects of various shapes and sizes. With ggrepel
you can solve the problem though it requires a bit of spatial data
processing with sf
-package.
ggplot() +
theme_light() +
geom_sf(data = polygon_uusimaa, alpha = .3) +
geom_sf(data = point_uusimaa) +
ggrepel::geom_text_repel(data = point_uusimaa %>%
sf::st_set_geometry(NULL) %>%
bind_cols(point_uusimaa %>%
sf::st_centroid() %>%
sf::st_coordinates() %>% as_tibble()),
aes(label = teksti, x = X, y = Y))
If want to present multiple variables of same regions you can use facets.
Facetting
is a useful way to present data on multiple variables covering the same
region. This is useful approach if you have, lets say, data on same
indicator from two different time points and you want to have separate
maps for separate times points, but have a shared scale. Below I create
a random data for two year titled population
and plot the
data using facet_wrap()
-function.
pop_data <- bind_rows(
tibble(
municipality_code = polygon$municipality_code
) %>%
mutate(population = rnorm(n = nrow(.), mean = 2000, sd = 250),
time = 2020),
tibble(
municipality_code = polygon$municipality_code
) %>%
mutate(population = rnorm(n = nrow(.), mean = 2000, sd = 250),
time = 2021)
)
pop_data
#> # A tibble: 618 × 3
#> municipality_code population time
#> <int> <dbl> <dbl>
#> 1 5 1802. 2020
#> 2 9 2386. 2020
#> 3 10 1770. 2020
#> 4 16 1820. 2020
#> 5 18 1814. 2020
#> 6 19 2004. 2020
#> 7 20 2293. 2020
#> 8 35 1934. 2020
#> 9 43 1611. 2020
#> 10 46 1629. 2020
#> # ℹ 608 more rows
pop_map <- right_join(polygon, pop_data)
ggplot(pop_map,
aes(fill = population)) +
geom_sf() +
facet_grid(~time)
However, often the indicators you want to compare either have different values (shared scale not ideal), are aggregated differently or cover non-overlapping geographic region. The you may find patchwork useful as in the example below.
library(patchwork)
p_municipalities <- ggplot(polygon, aes(fill = municipality_code)) +
geom_sf() +
theme(legend.position = "top")
p_regions <- ggplot(polygon %>% count(maakunta_code), aes(fill = maakunta_code)) +
geom_sf() +
theme(legend.position = "top")
p_uusimaa <- ggplot(polygon_uusimaa, aes(fill = municipality_code)) +
geom_sf() +
theme(legend.position = "top")
(p_municipalities | p_regions) /
p_uusimaa + plot_layout(nrow = 2, heights = c(1,0.6)) +
plot_annotation(title = "Combining multiple maps into a single (gg)plot")
Creating informative and aesthetically pleasing maps is always a
challenge and there are no recipe for instant success. Colors are
important and colorbrewer2.org
can help with that. In ggplot2
you can use
colorbrewer-palettes with scale_fill_brewer
,
scale_fill_distiller
, scale_fill_fermenter
-functions.
You may want to get rid of the grid as well as axis-labels and -titles.
ggplot(polygon_uusimaa, aes(fill = municipality_code)) +
geom_sf(color = alpha("white", 1/3)) +
scale_fill_fermenter(palette = "YlGnBu") +
theme_minimal() +
theme(axis.text = element_blank(),
axis.title = element_blank(),
panel.grid = element_blank(),
legend.position = "top"
) +
labs(title = "Municipality code",
fill = NULL)
As for interactive maps Leaflet is not the only option. For exploring you datasets in almost any CRS you should to try out mapview. As for larger datasets, you are probably safer with WebGL based mapdeck.
Again, I am most experienced with leaflet so the following example is
using leaflet. Leaflet default projection is EPSG:3857
or
WGS84
, also known as “Google Mercator” or “Web Mercator,
and you have reproject your geofi
data to plot it using
leaflet.
polygon_wgs84 <- sf::st_transform(x = polygon, crs = "+proj=longlat +datum=WGS84")
point_wgs84 <- sf::st_transform(x = point, crs = "+proj=longlat +datum=WGS84")
library(leaflet)
# lets create a palette for polygon fill (municipality codes)
pal <- leaflet::colorNumeric(palette = "Blues",
domain = polygon_wgs84$municipality_code)
# labels for localities
labels <- sprintf(
"<strong>%s</strong> (%s)",
point_wgs84$teksti, point_wgs84$kuntatunnus
) %>% lapply(htmltools::HTML)
# popup for polygons
popup <- sprintf(
"<strong>%s</strong> (%s)",
polygon_wgs84$municipality_name_fi, polygon_wgs84$municipality_code
) %>% lapply(htmltools::HTML)
EPSG3067 <- leaflet::leafletCRS(crsClass = "L.Proj.CRS",
code = "EPSG:3067",
proj4def = "+proj=utm +zone=35 +ellps=GRS80 +towgs84=0,0,0,0,0,0,0 +units=m +no_defs",
resolutions = 1.5^(25:15))
leaflet(polygon_wgs84, options = leafletOptions(worldCopyJump = F, crs = EPSG3067)) %>%
addProviderTiles(provider = providers$CartoDB.Positron) %>%
addPolygons(fillColor = ~pal(municipality_code),
color = "black",
weight = 1,
opacity = 1,
dashArray = "3",
fillOpacity = 0.4,
popup = popup,
highlight = highlightOptions(
weight = 2,
color = "#666",
dashArray = "",
fillOpacity = 0.4,
bringToFront = TRUE)
) %>%
addMarkers(data = point_wgs84,
label = labels,
clusterOptions = markerClusterOptions(),
labelOptions = labelOptions(opacity = .7,
style = list("font-weight" = "normal",
padding = "2px 4px"),
textsize = "12px",
direction = "auto"))