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This package provides tools for working with Gustavo Niemeyer's geohash system of nestable, compact global coordinates based on Z-order curves. The system consists of carving the earth into equally-sized rectangles (when projected into latitude/longitude space) and nesting this process recursively.
Originally, we adapted C++ source from Hiroaki Kawai, but have now rewritten the implementation completely with a new approach in C.
Encoding is the process of turning latitude/longitude coordinates into geohash strings. For example, Parque Nacional Tayrona in Colombia is located at roughly 11.3113917 degrees of latitude, -74.0779006 degrees of longitude. This can be expressed more compactly as:
library(geohashTools)
gh_encode(11.3113917, -74.0779006)
## [1] "d65267"
These 6 characters identify this point on the globe to within 1.2 kilometers (east-west) and .6 kilometers (north-south).
The park is quite large, and this is too precise to cover the park; we can "zoom out" by reducing the precision (which is the number of characters in the output, 6
by default):
gh_encode(11.3113917, -74.0779006, precision = 5L)
## [1] "d6526"
We can use this as a simple, regular level of spatial aggregation for spatial points data, e.g., counting presence of public art throughout the city of Chicago, as captured in a dataset
provided by the City:
NB: As of this writing, the Chicago data portal is down, apparently temporarily. However I'd like to submit this package update to CRAN in order to avoid deprecation issues around {rgdal} & co, so please check back on the website for a working version of the code below.
## first, pull the data internally from https://data.cityofchicago.org
# api_stem = 'https://data.cityofchicago.org/api/views'
# URL = file.path(api_stem, 'sj6t-9cju/rows.csv?accessType=DOWNLOAD')
# suppressPackageStartupMessages(library(data.table))
# art = fread(URL)
# count art by geohash
# gh_freq = art[, .N, by = .(geohash = gh_encode(LATITUDE, LONGITUDE, 5L))]
# only show the top 10
# gh_freq[order(-N)][1:10]
This is pretty impractical per se (where is dp3wm
?); we'll return to this once we've introduced more functionality.
The reverse of encoding geohashes is of course decoding them -- taking a given geohash string and converting it into global coordinates. For example, the Ethiopian coffee growing region of Yirgacheffe is roughly at sc54v
:
gh_decode('sc54v')
## $latitude
## [1] 6.130371
##
## $longitude
## [1] 38.21045
It can also be helpful to know just how precisely we've identified these coordinates; the include_delta
argument gives the cell half-widths in both directions in addition to the cell centroid:
gh_decode('sc54v', include_delta = TRUE)
## $latitude
## [1] 6.130371
##
## $longitude
## [1] 38.21045
##
## $delta_latitude
## [1] 0.02197266
##
## $delta_longitude
## [1] 0.02197266
In terms of latitude and longitude, all geohashes with the same precision have the same dimensions (though the physical size of the "rectangle" changes depending on the latitude); as such it's easy to figure out the cell half-widths from the precision alone using gh_delta
:
gh_delta(5L)
## [1] 0.02197266 0.02197266
One unfortunate consequence of the geohash system is that, while geohashes that are lexicographically similar (e.g. wxyz01
and wxyz12
) are certainly close to one another, the converse is not true -- for example, 7gxyru
and k58n2h
are neighbors! Put another way, small movements on the globe occasionally have visually huge jumps in the geohash-encoded output.
Fret not -- one tool for helping overcome this is the gh_neighbors
function (gh_neighbours
is also registered, for the Commonwealthy among us), which will return all of the geohashes adjacent to a given geohash (or vector of geohashes) at the same level of precision.
For example, the Merlion statue in Singapore is roughly at w21z74nz
, but this level of precision zooms in a bit too far. The geohash neighborhood thereof can be found with:
gh_neighbors('w21z74nz')
## $self
## [1] "w21z74nz"
##
## $southwest
## [1] "w21z74nw"
##
## $south
## [1] "w21z74ny"
##
## $southeast
## [1] "w21z74pn"
##
## $west
## [1] "w21z74nx"
##
## $east
## [1] "w21z74pp"
##
## $northwest
## [1] "w21z74q8"
##
## $north
## [1] "w21z74qb"
##
## $northeast
## [1] "w21z74r0"
geohashTools
offers several helper functions for interfacing your geohash objects with GIS tools in R, namely sp
and sf
. This will facilitate the best part of working with GIS data -- the visualizations!
Returning to public art locations in Chicago, we can visualize the spatial aggregations carried out above by converting to sp
, combining with a shapefile of Chicago, and plotting:
library(sf)
## first, pull neighborhood shapefiles from https://data.cityofchicago.org
# tmp = tempfile(fileext = '.zip')
# shp_url = file.path(
# api_stem, '9wp7-iasj', 'files',
# 'TMTPQ_MTmUDEpDGCLt_B1uaiJmwhCKZ729Ecxq6BPfM?filename=Neighborhoods_2012.zip'
# )
# download.file(shp_url, tmp)
# chicago = paste0('/vsizip/', tmp) |>
# st_read(quiet = TRUE) |>
# st_transform(crs = 4326L)
# artSF = gh_to_sf(
# art[, .N, by = .(geohash = gh_encode(LATITUDE, LONGITUDE, 6L))],
# gh_col = 'geohash'
# )
# plot(st_geometry(chicago), lwd = 0.5, main = 'Public Art Locations in Chicago')
# plot(artSF['N'], add = TRUE)
Chicago connoisseurs will recognize the biggest concentration around Lincoln Park, with another concentration along the waterfront near Millenium/Grant Parks.
The process for sf
is similar; just replace gh_to_spdf
with gh_to_sf
.
You might get benefit out of these more interactive online tools for working with geohashes: