cancensus can retrieve spatial data either on its own or packaged together with Census data.
You can specify whether you want data returned in an
sf-class data frame or as a
sp-class SpatialPolygonsDataFrame object. There are advantages to each spatial format. The
sf spatial framework is under development as the new principal spatial library for R and takes advantage of the Simple Features standard.
On the other hand,
sp has been around for a long time with development starting in the early 2000s and, as a result, it is a robust and well-maintained package with a large ecosystem of specialized packages that rely on it. First released in October 2016,
sf is a package still under development can be buggy and prone to breaking.
cancensus retrieves Census geographic data as GeoJSON objects and then converts them into either
sf objects depending on the
geo_format parameter input. The examples in this vignette assume
sf class geography.
sf package provides a wrapper around the base R
plot() function and largely works the same way with most of the same custom graphical parameters. One key thing about
sf.plot() is that it will plot every column of a sf data frame separately unless you specify a particular column. In this case, the household income variable we selected is stored in the
v_CA16_2397 column. Plotting it is easy.
You can specify titles, colour palettes, breaks, background colour, lines, borders, transparency, graticules, and much more by taking advantage of the available parameters. You can also combine layers of graphics objects made with
plot() by running different plots and adding the
add = TRUE parameter.
plot(st_geometry(toronto), col = NA, main = "Toronto CSDs with Median HH Income > $100,000", lty = 3) plot(st_geometry(toronto[toronto$median_hh_income > 100000,]), col = "red", add = TRUE)
sf objects with
ggplot2 is very straightforward with the built-in
geom_sf layer in the latest version of
ggplot2 supports all types of simple features and can automatically read and align CRS across multiple layers, can automatically adjust aspect ratio, and will automatically draw a graticule for your map. The advantage of using
ggplot2 for static maps is the customization and flexibility offered by the
ggplot2 layer and geom system.
An example of a basic map.
Or a similar map with all of the trimmings:
ggplot(toronto) + geom_sf(aes(fill = median_hh_income), colour = "grey") + scale_fill_viridis_c("Median HH Income", labels = scales::dollar) + theme_minimal() + theme(panel.grid = element_blank(), axis.text = element_blank(), axis.ticks = element_blank()) + coord_sf(datum=NA) + labs(title = "Median Household Income", subtitle = "Toronto Census Subdivisions, 2016 Census")
Leaflet for R can natively read in
sp class objects. Leaflet maps use a tile layer server to generate the base maps on which your data is plotted. There’s a number of different base layers available to use, although some require third party API keys. A gallery of available basemaps can be found here.
library(leaflet) leaflet(toronto) %>% addProviderTiles(providers$CartoDB.Positron) %>% addPolygons()
Adding colour ramps and additional interactivity takes a little bit more work but is still pretty easy to implement. Following this example we can specify the colour ramp to match our needs.
bins <- c(0, 30000,40000, 50000,60000, 70000,80000, 90000,100000, 110000, Inf) pal <- colorBin("RdYlBu", domain = toronto$v_CA16_2397, bins = bins) leaflet(toronto) %>% addProviderTiles(providers$CartoDB.Positron) %>% addPolygons(fillColor = ~pal(median_hh_income), color = "white", weight = 1, opacity = 1, fillOpacity = 0.65)