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_06-ex.Rmd
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_06-ex.Rmd
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Some of the exercises use a vector (`zion_points`) and raster dataset (`srtm`) from the **spDataLarge** package.
They also use a polygonal 'convex hull' derived from the vector dataset (`ch`) to represent the area of interest:
```{r 06-ex-e0, message=FALSE, include=TRUE}
library(sf)
library(terra)
library(spData)
zion_points_path = system.file("vector/zion_points.gpkg", package = "spDataLarge")
zion_points = read_sf(zion_points_path)
srtm = rast(system.file("raster/srtm.tif", package = "spDataLarge"))
ch = st_combine(zion_points) %>%
st_convex_hull() %>%
st_as_sf()
```
E1. Crop the `srtm` raster using (1) the `zion_points` dataset and (2) the `ch` dataset.
Are there any differences in the output maps?
Next, mask `srtm` using these two datasets.
Can you see any difference now?
How can you explain that?
```{r 06-ex-e1}
plot(srtm)
plot(st_geometry(zion_points), add = TRUE)
plot(ch, add = TRUE)
srtm_crop1 = crop(srtm, vect(zion_points))
srtm_crop2 = crop(srtm, vect(ch))
plot(srtm_crop1)
plot(srtm_crop2)
srtm_mask1 = mask(srtm, vect(zion_points))
srtm_mask2 = mask(srtm, vect(ch))
plot(srtm_mask1)
plot(srtm_mask2)
```
E2. Firstly, extract values from `srtm` at the points represented in `zion_points`.
Next, extract average values of `srtm` using a 90 buffer around each point from `zion_points` and compare these two sets of values.
When would extracting values by buffers be more suitable than by points alone?
```{r 06-ex-e2}
zion_points_buf = st_buffer(zion_points, dist = 90)
plot(srtm)
plot(st_geometry(zion_points_buf), add = TRUE)
plot(ch, add = TRUE)
zion_points_points = extract(srtm, vect(zion_points))
zion_points_buf = extract(srtm, vect(zion_points_buf))
plot(zion_points_points$srtm, zion_points_buf$srtm2)
```
E3. Subset points higher than 3100 meters in New Zealand (the `nz_height` object) and create a template raster with a resolution of 3 km for the extent of the new point dataset.
Using these two new objects:
- Count numbers of the highest points in each grid cell.
- Find the maximum elevation in each grid cell.
```{r 06-ex-e3}
nz_height3100 = dplyr::filter(nz_height, elevation > 3100)
new_graticule = st_graticule(nz_height3100, datum = "EPSG:2193")
plot(st_geometry(nz_height3100), graticule = new_graticule, axes = TRUE)
nz_template = rast(ext(nz_height3100), resolution = 3000, crs = crs(nz_height3100))
nz_raster = rasterize(vect(nz_height3100), nz_template,
field = "elevation", fun = "length")
plot(nz_raster)
plot(st_geometry(nz_height3100), add = TRUE)
nz_raster2 = rasterize(vect(nz_height3100), nz_template,
field = "elevation", fun = max)
plot(nz_raster2)
plot(st_geometry(nz_height3100), add = TRUE)
```
E4. Aggregate the raster counting high points in New Zealand (created in the previous exercise), reduce its geographic resolution by half (so cells are 6 by 6 km) and plot the result.
- Resample the lower resolution raster back to the original resolution of 3 km. How have the results changed?
- Name two advantages and disadvantages of reducing raster resolution.
```{r 06-ex-e4}
nz_raster_low = raster::aggregate(nz_raster, fact = 2, fun = sum, na.rm = TRUE)
res(nz_raster_low)
nz_resample = resample(nz_raster_low, nz_raster)
plot(nz_raster_low)
plot(nz_resample) # the results are spread over a greater area and there are border issues
plot(nz_raster)
```
```{asis}
Advantages:
- lower memory use
- faster processing
- good for viz in some cases
Disadvantages:
- removes geographic detail
- adds another processing step
```
E5. Polygonize the `grain` dataset and filter all squares representing clay.
```{r 06-ex-e5}
grain = rast(system.file("raster/grain.tif", package = "spData"))
```
- Name two advantages and disadvantages of vector data over raster data.
- When would it be useful to convert rasters to vectors in your work?
```{r 06-ex-e5-2}
grain_poly = as.polygons(grain) %>%
st_as_sf()
levels(grain)
clay = dplyr::filter(grain_poly, grain == "clay")
plot(clay)
```
```{asis}
Advantages:
- can be used to subset other vector objects
- can do affine transformations and use sf/dplyr verbs
Disadvantages:
- better consistency
- fast processing on some operations
- functions developed for some domains
```