Our analysis area is the Morasko Meteorite nature reserve located in
the Greater Poland voivodeship. It was established in 1976 in order to
protect the area of impact craters, which, according to researchers,
were formed in the fall of the Morasko meteorite about 5,000 years ago.
In addition, the oak-hornbeam forest with rare species of plants
(lilium martagon, ceratophyllum submersum) and birds
(european nightjar, black woodpecker) is
protected.
Vector data
The centroid (geometric center) of the Morasko Meteorite nature
reserve has X = 16.895 and Y = 52.487 coordinates in World Geodetic
System 1984 (EPSG 4326). Let’s start by creating this point with the
sf package.
morasko = st_point(c(16.895, 52.489))
morasko = st_sfc(morasko, crs = 4326) # set coordinate system
morasko
## Geometry set for 1 feature
## Geometry type: POINT
## Dimension: XY
## Bounding box: xmin: 16.895 ymin: 52.489 xmax: 16.895 ymax: 52.489
## Geodetic CRS: WGS 84
## POINT (16.895 52.489)
Now our point is embedded in space (has a spatial reference). In the
next step, let’s create an approximate zone that will include the area
of the reserve. The function st_buffer() will be used for
this. Before this operation, we need to transform the coordinate system
to a system with metric units, e.g. Poland CS92 (EPSG 2180), using
st_transform() function.
morasko = st_transform(morasko, crs = 2180)
morasko_buffer = st_buffer(morasko, dist = 400)
We have created a buffer with a radius of 400 meters. Let’s visualize
it.
plot(morasko_buffer, axes = TRUE, main = "Morasko reserve buffer")
plot(morasko, add = TRUE)
Of course, the area shown above is not exactly the reserve area. The
exact area can be determined from the polygon layer as in orthophotomap
example using the General Geographic Database.
Raster data
Now we can search for available elevation data for this area using
the DEM_request() function (it is analogous to the
ortho_request() function). The only argument of the
function is our reserve buffer.
req_df = DEM_request(morasko_buffer)
Let’s check the obtained results.
# display the first 10 rows and the first 5 columns
req_df[1:10, 1:5]
## sheetID year format resolution avgElevErr
## 1 N-33-130-D-b-1 2007 Intergraph TTN <NA> 1.5
## 2 N-33-130-D-b-1-1 2020 ARC/INFO ASCII GRID 5.0 m 0.5
## 3 N-33-130-D-b-1-1 2017 ASCII XYZ GRID 1.0 m 0.9
## 4 N-33-130-D-b-1-1 2012 ARC/INFO ASCII GRID 0.5 m 0.1
## 5 6.179.11.13.4 2018 ASCII TBD 1.0 m 0.1
## 6 6.179.11.14.1 2018 ASCII TBD 1.0 m 0.1
## 7 6.179.11.08.4 2018 ASCII TBD 1.0 m 0.1
## 8 6.179.11.14.3 2018 ASCII TBD 1.0 m 0.1
## 9 6.179.11.09.3 2018 ASCII TBD 1.0 m 0.1
## 10 6.179.11.13.2 2018 ASCII TBD 1.0 m 0.1
We have received metadata with many types of data of different
formats, timeliness, resolution, and accuracy. For our analysis, we need
digital terrain model (DTM) and digital surface model (DSM) in the
“ARC/INFO ASCII GRID” format. Let’s make data selection by creating two
tables and combining them together.
req_df_DTM = req_df[req_df$format == "ARC/INFO ASCII GRID" &
req_df$product == "DTM" &
req_df$year == 2019, ]
req_df_DSM = req_df[req_df$format == "ARC/INFO ASCII GRID" &
req_df$product == "DSM" &
req_df$year == 2019, ]
# combine data tables
req_df = rbind(req_df_DTM, req_df_DSM)
req_df[, 1:5]
## sheetID year format resolution avgElevErr
## 39 N-33-130-D-b-1-1 2019 ARC/INFO ASCII GRID 1.0 m 0.1
## 11 N-33-130-D-b-1-1 2019 ARC/INFO ASCII GRID 0.5 m 0.1
Now we can download the data using the tile_download()
function with our filtered data frame as input.
# 168.7 MB
tile_download(req_df, outdir = "./data")
## 1/2
## 2/2
If you run into any problem with the download, remember that you can
pass another download method from download.file() as a
function argument.
tile_download(req_df, outdir = "./data", method = "wget")
Processing
Let’s load the downloaded numerical models using the
read_stars() function from the stars
package, which allows working on spatiotemporal arrays. We have two
files, one represents DTM and second represents DSM.
# load data
DTM = read_stars("data/73044_917579_N-33-130-D-b-1-1.asc", proxy = FALSE)
DSM = read_stars("data/73043_917495_N-33-130-D-b-1-1.asc", proxy = FALSE)
# name raster
names(DTM) = "DTM"
names(DSM) = "DSM"
# set coordinate system
st_crs(DTM) = 2180
st_crs(DSM) = 2180
You probably noticed the four-fold difference in their sizes. It is
due to the difference between their cells resolutions. We need to unify
them to a common resolution to be able to combine them into one stack.
It is much better to use a lower resolution than to increase it, because
we cannot get more information and the processing will be faster. Let’s
use the st_warp() function to do this.
DSM = st_warp(DSM, dest = DTM, cellsize = 1)
Now, both models have the same dimensions (the number of rows and
columns) and spatial resolution. Thus, we can combine them into one
object (DEM).
DEM = c(DTM, DSM)
length(DEM)
## [1] 2
Now we have a DEM object that consists of two attributes (DTM and
DSM). In fact, both attributes contains same type of data as they are
representing elevation. Therefore, we can collapse the attributes into a
new dimension. Let’s do that using st_redimension().
DEM = st_redimension(DEM)
names(st_dimensions(DEM))[3] = "elev" # name new data dim
st_dimensions(DEM)
## from to offset delta refsys point values x/y
## x 1 2188 355733 1 ETRS89 / Poland CS92 TRUE NULL [x]
## y 1 2379 517029 -1 ETRS89 / Poland CS92 TRUE NULL [y]
## elev 1 2 NA NA NA NA DTM, DSM
After this operation, our elevation attribute consists of the DTM and
DSM layers (dimensions). Then let’s crop the rasters to our buffer.
DEM = st_crop(DEM, morasko_buffer)
Let’s check what the result looks like.
plot(DEM, col = terrain.colors(99, alpha = NULL))
In the first quadrant of the circle, we can see five smaller circles.
These are the craters formed after the impact of the Morasko meteorite.
The largest fragment found weighs 272 kg and it is the largest meteorite
found in Poland. The collection of found meteorites can be seen at the
Earth Museum in
Poznań.
Let’s calculate the crater width using the terrain transverse
profile. We can use our centroid and add a second example point 30
degrees towards N. Next, we connect these points into a line
(st_linestring()) and then sample this line every 1 m
(st_line_sample()), because our DEM has this resolution. As
a result, we get one complex geometry (MULTIPOINT), which we
have to convert into a simple geometry (POINT) consisting of
many points. The function st_cast() is used for this.
pts_matrix = matrix(c(357121.7, 515765.5,
357321.2, 516017.9),
ncol = 2, byrow = TRUE)
line = st_sfc(st_linestring(pts_matrix), crs = 2180)
line = st_line_sample(line, density = 1)
line = st_cast(line, "POINT")
# plot DTM (first layer)
plot(DEM[, , , 1], main = "DTM [m]", col = terrain.colors(99, alpha = NULL),
reset = FALSE)
plot(line, col = "red", add = TRUE)
In the last step, we extract the elevation values for these points
using st_extract().
# take elevation from DTM and DSM layers
elev_line = st_extract(DEM, line)[[1]]
colnames(elev_line) = c("DTM", "DSM")
Now we can see how our transverse profile looks like.
# use 'dev.off()' to reset previous plot
plot(elev_line[, "DTM"], type = "l", main = "Digital terrain model",
ylab = "Elevation [m]", xlab = "Distance [m]", col = "red")
abline(v = c(126, 219), col = "blue")
The largest width of the impact crater is about 90 m.
Okay, we checked the terrain. In the last step, let’s examine the
height of the objects on it. For this purpose, we calculate the height
of the trees by subtracting the DTM from the DSM. The product of this
difference is called normalized DSM, because it takes the terrain
elevation as a reference.
calc = function(DEM) (DEM[2] - DEM[1])
nDSM = st_apply(DEM, MARGIN = c("x", "y"), FUN = calc)
plot(nDSM, main = "Trees height [m]",
col = hcl.colors(9, palette = "Greens", rev = TRUE))
