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raem
does not contain functions to export output to
spatial data formats such as vector data or rasters. Other R packages do
have this functionality however. This vignette describes a way to create
spatial data from raem
output using other,
well-established, packages.
As an example model, two extraction wells in a phreatic aquifer with uniform background flow and areal recharge are modeled. The output grid is defined and head contours are plotted.
library(raem)
# aquifer parameters
k = 10 # hydraulic conductivity, m/d
top = 30 # aquifer top elevation, m
base = 0 # aquifer bottom elevation, m
n = 0.2 # aquifer effective porosity, -
# create elements
w1 = well(x = -500, y = 100, Q = 1000)
w2 = well(x = 300, -200, Q = 1200)
as = areasink(x = 0, y = 0, R = 1500, N = 0.3 / 365)
uf = uniformflow(TR = k * (top - base), gradient = 0.002, angle = -135) # SW direction
rf = constant(x = 1000, y = 1000, h = 25)
# create and solve model
m = aem(k, top, base, n, w1, w2, as, uf, rf)
# output grid
xg = seq(-1200, 1000, length = 100)
yg = seq(-700, 500, length = 100)
# plot head contours
contours(m, xg, yg, col = 'dodgerblue', nlevels = 20, labcex = 0.8,
xlab = 'x (m)', ylab = 'y (m)')
The contours can be exported as a spatial vector format using the sf and isoband packages. sf
is widely used in the R community to handle spatial vector data.
isoband
is a lightweight package containing fast contouring
algorithms used in i.a. ggplot2. A contouring grid of
the variable of interest is required. Optionally, the origin of the
raem
model grid at \((x, y) =
(0,0)\) can be specified in a projected coordinate system so that
the exported contours are georeferenced. The set of contour lines is
generated with isoband::isolines()
and converted to a
sf
simple feature geometry collection, which can then be
used as a simple feature geometry column in a sf
simple
feature object.
library(sf)
library(isoband)
# create a 10 by 10 m contouring grid and get the heads as a grid
xg = seq(-1200, 1000, by = 10)
yg = seq(-700, 500, by = 10)
h = heads(m, xg, yg, as.grid = TRUE)
# optionally, set the x and y origin corresponding to (0, 0)
# in the requested coordinate system
xorigin = 195600
yorigin = 203500
epsg = 31370
# create the isolines with the specified levels
# the y-coordinates need to be reversed here for isolines()
lvls = seq(13.5, 24.5, by = 0.5)
isolines = isolines(xg + xorigin,
rev(yg) + yorigin,
h,
levels = lvls)
# convert to sfg object, create sfc column for sf object
isolines_sf = st_sf(level = as.numeric(names(isolines)),
geometry = st_sfc(iso_to_sfg(isolines)),
crs = epsg)
plot(isolines_sf)
To export the sf
object to disk, the sf
package provides the write_sf()
function:
To create and export output as a spatial raster object such as a GeoTIFF, the terra package can be used. This package is the replacement of the older, widely popular raster package. Similar to the creation of a spatial vector object, a grid of values for the variable of interest (here hydraulic head) needs to be specified. Optionally, the origin coordinates can be given to georeference the output. The extent of the raster needs to be specified explicitly from the range of the marginal grid vectors.
library(terra)
# set extent and create raster
extent = c(range(xg) + xorigin, range(yg) + yorigin)
r = rast(h, crs = paste('epsg', epsg, sep = ':'), extent = ext(extent))
# plot
plot(r)
To export the raster to disk, use the writeRaster()
function from the terra
package:
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.