R bindings to H3, a hexagon-based geographic grid system via h3-js.
R bindings via native H3 C library can be found at
h3r. h3r is much faster but
requires installing h3 separately.
WARNING Only functions that take non-array input support vectorized operations currently. The return value of other functions when applying vectorized input may be unspecified. You should map over those input instead.
You can install the released version of h3js from CRAN with:
install.packages("h3js")Development version can be installed with:
devtools::install_github("saurfang/h3js")library(h3js)
library(sf)
library(tidyverse)
# Convert a lat/lng point to a hexagon index at resolution 7
h3_index <- h3_geo_to_h3(37.3615593, -122.0553238, 7)
h3_index
#> [1] "87283472bffffff"
# Get the center of the hexagon
hex_center_coordinates <- h3_to_geo(h3_index)
hex_center_coordinates
#> [1] 37.35172 -122.05033
# Get the vertices of the hexagon
hex_boundary <- h3_to_geo_boundary(h3_index)
hex_boundary
#> [,1] [,2]
#> [1,] 37.34110 -122.0416
#> [2,] 37.35290 -122.0340
#> [3,] 37.36352 -122.0428
#> [4,] 37.36234 -122.0591
#> [5,] 37.35054 -122.0666
#> [6,] 37.33992 -122.0579
hex_boundary %>%
# close polygon
rbind(.[1,]) %>%
# swap columns
.[, c(2, 1)] %>%
# convert to simple feature collection
list() %>%
st_polygon() %>%
st_sfc() %>%
plot()
# Get all neighbors within 1 step of the hexagon
h3_k_ring(h3_index, 1)
#> [1] "87283472bffffff" "87283472affffff" "87283470cffffff" "87283470dffffff"
#> [5] "872834776ffffff" "872834729ffffff" "872834728ffffff"
# Get the set of hexagons within a polygon
polygon <- list(
c(37.813318999983238, -122.4089866999972145),
c(37.7198061999978478, -122.3544736999993603),
c(37.8151571999998453, -122.4798767000009008)
)
hexagons <- h3_polyfill(polygon, 7)
hexagons
#> [1] "872830828ffffff" "87283082effffff" "87283082affffff" "87283082bffffff"
#> [5] "872830876ffffff" "872830820ffffff" "872830870ffffff"
# Get the outline of a set of hexagons, as a GeoJSON-style MultiPolygon
coordinates <- h3_set_to_multi_polygon(hexagons, TRUE)
c(
coordinates %>%
map(~ matrix(.x, ncol = 2)) %>%
map(list) %>%
st_multipolygon() %>%
st_sfc(),
do.call(rbind, polygon) %>%
# close polygon
rbind(.[1,]) %>%
# swap columns
.[, c(2, 1)] %>%
list %>%
st_polygon() %>%
st_sfc()
) %>%
st_sf() %>%
plot()
Houston <- list(lat = 29.7632836, lon = -95.3632715)
# single arguments
microbenchmark::microbenchmark(
h3r::getIndexFromCoords(Houston$lat, Houston$lon, resolution = 5),
h3_geo_to_h3(Houston$lat, Houston$lon, res = 5),
h3r::getBoundingHexFromCoords(Houston$lat, Houston$lon, resolution = 5),
h3_to_geo_boundary(h3_geo_to_h3(Houston$lat, Houston$lon, res = 5))
)
#> Unit: microseconds
#> expr
#> h3r::getIndexFromCoords(Houston$lat, Houston$lon, resolution = 5)
#> h3_geo_to_h3(Houston$lat, Houston$lon, res = 5)
#> h3r::getBoundingHexFromCoords(Houston$lat, Houston$lon, resolution = 5)
#> h3_to_geo_boundary(h3_geo_to_h3(Houston$lat, Houston$lon, res = 5))
#> min lq mean median uq max neval
#> 11.572 24.7375 41.46644 39.6285 52.1510 122.485 100
#> 742.427 1147.9030 1995.58544 1601.6880 2330.8450 11489.859 100
#> 17.031 27.6205 221.48883 50.7200 70.5675 16793.250 100
#> 1500.967 2104.0835 3411.27699 2920.7360 3930.8230 14837.502 100
# vectorized input
coordinates <- list(lat = runif(100, -90, 90), lon = runif(100, -180, 180))
microbenchmark::microbenchmark(
pmap(coordinates, ~h3r::getIndexFromCoords(.x, .y, resolution = 5)),
h3_geo_to_h3(coordinates$lat, coordinates$lon, res = 5)
)
#> Unit: microseconds
#> expr
#> pmap(coordinates, ~h3r::getIndexFromCoords(.x, .y, resolution = 5))
#> h3_geo_to_h3(coordinates$lat, coordinates$lon, res = 5)
#> min lq mean median uq max neval
#> 1508.317 1847.437 3011.063 2236.570 2907.621 38565.621 100
#> 817.205 1114.620 1768.592 1368.635 1822.631 8248.186 100