Chapter 6 Raster processing
Last updated: 2022-02-21 17:09:27
Aims
Our aims in this chapter are:
- Learn how to get raster subsets
- Learn to set raster dimension properties
- Learn to calculate new rasters, based on one or more overlapping rasters, using raster algebra
We will use the following R packages:
stars
6.1 Time series for single pixel
6.1.1 Selecting pixel by row & column
In most of the examples in this chapter, we are going to use the MOD13A3_2000_2019.tif
raster which we already met in Section 5.3. Let’s read it into memory:
library(stars)
= read_stars("MOD13A3_2000_2019.tif")
r names(r) = "NDVI"
Keep in mind this is a raster time series, where the “layers” refer to NDVI images taken in different times. As an exercise of accessing raster values (Section 5.3.8.4) and working with time series (Section 3.1.3), in this Section we are going to extract and plot a NDVI time series for a single pixel.
In Section 5.3.8.2, we saw how the matrix
or array
of raster values can be accessed using the [[
operator, as in r[[1]]
. As another exercise, let’s access a “slice” of a single pixel through all of the raster layers, as follows:
= r[[1]][50, 220, ]
v class(v)
## [1] "numeric"
The result is a vector (why?). Plotting the vector displays a time-series of NDVI at a particular location (Figure 6.1):
plot(v, type = "o")
Now, let us improve the time series plot, by:
6.1.2 Combining values with dates
The file MOD13A3_2000_2019_dates2.csv
corresponds to the third dimension of MOD13A3_2000_2019.tif
, containing the dates when each NDVI image was captured. This file includes the additional season
column which we calculated in Section 4.6.
Using the MOD13A3_2000_2019_dates2.csv
table, we can display dates on the x-axis (Figure 6.2). First we read the dates table:
= read.csv("MOD13A3_2000_2019_dates2.csv")
dates $date = as.Date(dates$date) dates
Then we can plot the dates on the x-axis, as follows:
plot(dates$date, v, type = "o", xlab = "Time", ylab = "NDVI")
6.1.3 Visualizing seasonal pattern
Figure 6.2 clearly shows the seasonal pattern of NDVI. However, we can further improve the interpretability of the time series plot if we mark seasons with different color. One way to do that is to plot the NDVI observations of each season one at a time, using a for
loop.
As a first step, we define the vector of seasons (seasons
) and the corresponding vector of colors (cols
):
= c("winter", "spring", "summer", "fall")
seasons = c("blue", "purple", "red", "yellow") cols
Then, we can use a for
loop (Section 4.2.3) to mark the portion of the NDVI time series from each season (Figure 6.3):
plot(dates$date, v, type = "l", xlab = "Time", ylab = "NDVI", col = "grey")
for(i in 1:length(seasons)) {
= v
tmp $season != seasons[i]] = NA
tmp[dateslines(dates$date, tmp, col = cols[i], type = "o")
}
6.2 Raster subsetting
6.2.1 Selecting rows, column and layers
We can get a subset of a stars
object while keeping all of its properties, using the [
operator.
The stars
subset operator [
works as follows:
- The 1st index selects attributes
- The 2nd index selects the first dimension, typically
[x]
, i.e., raster columns - The 3rd index selects the second dimension, typically
[y]
, i.e., raster rows - The 4th index selects the third dimension (if there is one), typically
band
, i.e., raster layers - (Subsequesnt indices, if any, select the remaining dimensions)
In this book, as well as in most spatial data analysis practices, we encounter two types of rasters: single-band rasters and multi-band rasters (Section 5.3.2). Accordingly, typical subsetting of stars
objects requires either 3 or 4 indices, where the first index is left blank (since there is only one attribute). Again (Section 5.3.8.4), keep in mind that the order of stars
indices is opposite of the order we are used to in R, since the first dimension refers to columns [x]
, while the second dimension refers to rows [y]
.
For example, the following expression creates a subset with two columns, three rows and four layers from r
:
= r[, 100:101, 200:202, 2:5]
s
s## stars object with 3 dimensions and 1 attribute
## attribute(s):
## Min. 1st Qu. Median Mean 3rd Qu. Max.
## NDVI 0.1575 0.1841 0.2261 0.2235417 0.2696 0.2852
## dimension(s):
## from to offset delta refsys point values x/y
## x 100 101 3239946 926.625 unnamed FALSE NULL [x]
## y 200 202 3717158 -926.625 unnamed FALSE NULL [y]
## band 2 5 NA NA NA NA NULL
The raster subset is plotted in Figure 6.4:
plot(round(s, 2), text_values = TRUE, col = terrain.colors(6), key.pos = 4)
Note that we use the round
function to round all raster values to two decimal places, so that the text labels can fit inside the pixels. This is an example of a raster algebra operation, which we learn about later in this chapter (Section 6.4).
What is the meaning of the following plot (Figure 6.5)?
plot(
as.vector(r[,,,2][[1]]),
as.vector(r[,,,3][[1]]),
xlab = "Band 2",
ylab = "Band 3"
)
6.2.2 Dropping unnecessary dimensions
When a subset includes just one step along one or more dimensions, the “unnecessary” demensions can be dropped using drop=TRUE
. For example, compare the output of the following two expressions. Both expressions return a subset consisting of the 7th layer of r
. However, the first expression returns a three-dimensional stars
object (with a single layer in the 3rd dimension), while the second expression returns a two-dimensional stars
object where the 3rd dimension was “dropped”:
7]
r[,,,## stars object with 3 dimensions and 1 attribute
## attribute(s):
## Min. 1st Qu. Median Mean 3rd Qu. Max. NA's
## NDVI -0.1986 0.0959 0.1117 0.1482469 0.1887 0.8518 9877
## dimension(s):
## from to offset delta refsys point values x/y
## x 1 167 3239946 926.625 unnamed FALSE NULL [x]
## y 1 485 3717158 -926.625 unnamed FALSE NULL [y]
## band 7 7 NA NA NA NA NULL
7, drop = TRUE]
r[,,,## stars object with 2 dimensions and 1 attribute
## attribute(s):
## Min. 1st Qu. Median Mean 3rd Qu. Max. NA's
## NDVI -0.1986 0.0959 0.1117 0.1482469 0.1887 0.8518 9877
## dimension(s):
## from to offset delta refsys point values x/y
## x 1 167 3239946 926.625 unnamed FALSE NULL [x]
## y 1 485 3717158 -926.625 unnamed FALSE NULL [y]
Accordingly, the raster values are represented as an array
in the first case, and as a matrix
in the second case:
class(r[,,,7][[1]])
## [1] "array"
class(r[,,,7, drop = TRUE][[1]])
## [1] "matrix" "array"
Note that the meaning of the drop
parameter in stars
subsetting differs from what we learned about in data.frame
(Section 4.1.5.3) and matrix
(Section 5.1.7.1) subsetting, in two respects. First, in stars
subsetting, drop=TRUE
specifies dropping of raster dimensions, while in data.frame
and matrix
subsetting, drop
specifies simplifying to a different data structure (a vector). Second, the default of drop
in stars
is drop=FALSE
; in data.frame
and matrix
subsetting, the default is drop=TRUE
.
6.3 Raster dimensions
6.3.1 Getting dimension properties
As mentioned in Section 5.3.8.3, the st_dimensions
function can be used to access dimension properties of a stars
object. The function resurns an object of class dimensions
. Printing the object gives all information on the raster dimensions in the form of a table:
st_dimensions(r)
## from to offset delta refsys point values x/y
## x 1 167 3239946 926.625 unnamed FALSE NULL [x]
## y 1 485 3717158 -926.625 unnamed FALSE NULL [y]
## band 1 233 NA NA NA NA NULL
Internally, the dimensions
object is a list
of dimensions, with one list
element per dimension. Each element is also a list
, with the internal list
elements being the various properties of a single dimension:
str(st_dimensions(r))
## List of 3
## $ x :List of 7
## ..$ from : num 1
## ..$ to : num 167
## ..$ offset: num 3239946
## ..$ delta : num 927
## ..$ refsys:List of 2
## .. ..$ input: chr "unnamed"
## .. ..$ wkt : chr "PROJCRS[\"unnamed\",\n BASEGEOGCRS[\"unnamed ellipse\",\n DATUM[\"unknown\",\n ELLIPSOID[\"| __truncated__
## .. ..- attr(*, "class")= chr "crs"
## ..$ point : logi FALSE
## ..$ values: NULL
## ..- attr(*, "class")= chr "dimension"
## $ y :List of 7
## ..$ from : num 1
## ..$ to : num 485
## ..$ offset: num 3717158
## ..$ delta : num -927
## ..$ refsys:List of 2
## .. ..$ input: chr "unnamed"
## .. ..$ wkt : chr "PROJCRS[\"unnamed\",\n BASEGEOGCRS[\"unnamed ellipse\",\n DATUM[\"unknown\",\n ELLIPSOID[\"| __truncated__
## .. ..- attr(*, "class")= chr "crs"
## ..$ point : logi FALSE
## ..$ values: NULL
## ..- attr(*, "class")= chr "dimension"
## $ band:List of 7
## ..$ from : num 1
## ..$ to : int 233
## ..$ offset: num NA
## ..$ delta : num NA
## ..$ refsys: chr NA
## ..$ point : logi NA
## ..$ values: NULL
## ..- attr(*, "class")= chr "dimension"
## - attr(*, "raster")=List of 3
## ..$ affine : num [1:2] 0 0
## ..$ dimensions : chr [1:2] "x" "y"
## ..$ curvilinear: logi FALSE
## ..- attr(*, "class")= chr "stars_raster"
## - attr(*, "class")= chr "dimensions"
Individual dimensions can be accessed using the $
operator by list
element name, or the [[
operator by list element index or name (more on lists in Section 11.1). For example, all three expressions shown below return the same result, the properties of the 1st dimension "x"
:
str(st_dimensions(r)[[1]])
## List of 7
## $ from : num 1
## $ to : num 167
## $ offset: num 3239946
## $ delta : num 927
## $ refsys:List of 2
## ..$ input: chr "unnamed"
## ..$ wkt : chr "PROJCRS[\"unnamed\",\n BASEGEOGCRS[\"unnamed ellipse\",\n DATUM[\"unknown\",\n ELLIPSOID[\"| __truncated__
## ..- attr(*, "class")= chr "crs"
## $ point : logi FALSE
## $ values: NULL
## - attr(*, "class")= chr "dimension"
str(st_dimensions(r)[["x"]])
## List of 7
## $ from : num 1
## $ to : num 167
## $ offset: num 3239946
## $ delta : num 927
## $ refsys:List of 2
## ..$ input: chr "unnamed"
## ..$ wkt : chr "PROJCRS[\"unnamed\",\n BASEGEOGCRS[\"unnamed ellipse\",\n DATUM[\"unknown\",\n ELLIPSOID[\"| __truncated__
## ..- attr(*, "class")= chr "crs"
## $ point : logi FALSE
## $ values: NULL
## - attr(*, "class")= chr "dimension"
str(st_dimensions(r)$x)
## List of 7
## $ from : num 1
## $ to : num 167
## $ offset: num 3239946
## $ delta : num 927
## $ refsys:List of 2
## ..$ input: chr "unnamed"
## ..$ wkt : chr "PROJCRS[\"unnamed\",\n BASEGEOGCRS[\"unnamed ellipse\",\n DATUM[\"unknown\",\n ELLIPSOID[\"| __truncated__
## ..- attr(*, "class")= chr "crs"
## $ point : logi FALSE
## $ values: NULL
## - attr(*, "class")= chr "dimension"
Properties of individual dimensions can be accessed through further subsetting (Figure 6.6). For example, the following expression returns the offset
(origin) and delta
(resolution) of the "x"
dimension of raster r
:
st_dimensions(r)$x$delta
## [1] 926.6254
st_dimensions(r)$x$offset
## [1] 3239946
The meanings of the seven properties that every stars
dimension has are summarized in Table 6.1.
Property | Contents | Description |
---|---|---|
from |
numeric length 1 |
The start index |
to |
numeric length 1 |
The end index |
offset |
numeric length 1 |
The start coordinate (or time) of the first element (e.g., the pixel/cell boundary) |
delta |
numeric length 1 |
The increment / cell size (e.g., the resolution) |
refsys |
character , or crs |
The Coordinate Reference System (e.g., the CRS) |
point |
logical length 1 |
Whether cells/pixels refer to areas/periods (FALSE ), or to points/instances (TRUE ) |
values |
NULL , or an object that gives the specific dimension values |
The dimension values, in case they are not calculated from offset and delta |
For more information on stars
dimensions, see the official stars
Data Model article.
6.3.2 Setting dimension properties
A .tif
file cannot hold metadata regarding raster “layers”, such as the date when the images were captured in case the layers comprise a time series, or the band names in case the layers comprise spectral bands (Section 6.4.2). Accordingly, the third dimension of a stars
object created from GeoTIFF file does not contain any information other than the from
and to
indices (e.g., 1
and 233
):
st_dimensions(r)
## from to offset delta refsys point values x/y
## x 1 167 3239946 926.625 unnamed FALSE NULL [x]
## y 1 485 3717158 -926.625 unnamed FALSE NULL [y]
## band 1 233 NA NA NA NA NULL
We can incorporate more information into a stars
object dimensions, or modify the existing information, on our own. This is done using function st_set_dimensions
, where we need to specify:
.x
—Thestars
objectwhich
—The index (e.g.,1
) or name (e.g.,"x"
) of the dimension to be modified
as well as the dimension properties and their new values, such as:
offset
—The offset (i.e., origin)delta
—The delta (i.e., resolution)25values
—The values along the dimensionnames
—The new dimension names
as in st_set_dimensions(r, "x", offset = 0, delta = 1000)
.
Additionally, the names of all dimensions can be modified using (i.e., without specifying which
):
.x
— Thestars
objectnames
—The new dimension names
as in st_set_dimensions(r, names = c("a", "b", "c"))
.
For example, for a non-spatial dimension that represents time, such as the "band"
dimension in r
, we can:
- set the values to the corresponding dates or time (such as
Date
values), and - change the dimension name to
time
,
as follows:
= st_set_dimensions(r, "band", names = "time", values = dates$date) r
Now, the 3rd dimension of r
is named "time"
and contains the Date
values:
st_dimensions(r)
## from to offset delta refsys point values x/y
## x 1 167 3239946 926.625 unnamed FALSE NULL [x]
## y 1 485 3717158 -926.625 unnamed FALSE NULL [y]
## time 1 233 NA NA Date NA 2000-02-15,...,2019-06-15
If necessary, the dimension values can be read back using st_get_dimension_values
. For example:
= st_get_dimension_values(r, "time")
z class(z)
## [1] "Date"
1:10]
z[## [1] "2000-02-15" "2000-03-15" "2000-04-15" "2000-05-15" "2000-06-15"
## [6] "2000-07-15" "2000-08-15" "2000-09-15" "2000-10-15" "2000-11-15"
What is the meaning of the dimension values given by
st_get_dimension_values(r, "x")
andst_get_dimension_values(r, "y")
? Given thatst_dimensions(r)$y$values
andst_dimensions(r)$y$values
areNULL
, where do you think these dimension values come from?
Why do we need to bother with editing or supplementing dimension properties? One reason is that it is more convenient to have all of the relevant raster data in the same object (rather than two separate objects, such as r
and dates
). Moreover, information regarding stars
dimensions is utilized by stars
functions in various contexts. For example, the layer values apprear as labels in plot
output panels (Figure 6.7):
plot(r[,,,1:5], breaks = "equal", col = hcl.colors(11, "Spectral"), key.pos = 4)
or as column values when converting from stars
to data.frame
:
head(as.data.frame(r))
## x y time NDVI
## 1 3240409 3716695 2000-02-15 NA
## 2 3241336 3716695 2000-02-15 NA
## 3 3242262 3716695 2000-02-15 NA
## 4 3243189 3716695 2000-02-15 NA
## 5 3244116 3716695 2000-02-15 NA
## 6 3245042 3716695 2000-02-15 NA
6.3.3 Converting a matrix
to raster
6.3.3.1 The volcano
matrix
Converting a matrix
to a stars
raster is rarely needed in practice, since most of the time you will be working with existing rasters imported from files (Section 5.3.2). However, experimenting with the matrix
→stars
conversion will help us better understand the nature of rasters, in general, and of the stars
class, in particular.
When converting a matrix
or an array
to a stars
raster, we must manually set the properties of the dimensions, most importantly the spatial dimensions "x"
and "y"
.
In the first example, we will convert the built-in volcano
matrix (Section 5.1.6) to a stars
raster. First, we convert the transposed (why? see Section 5.3.8.4) matrix
to a stars
raster, using function st_as_stars
:
= st_as_stars(t(volcano))
v
v## stars object with 2 dimensions and 1 attribute
## attribute(s):
## Min. 1st Qu. Median Mean 3rd Qu. Max.
## A1 94 108 124 130.1879 150 195
## dimension(s):
## from to offset delta refsys point values x/y
## X1 1 61 0 1 NA FALSE NULL [x]
## X2 1 87 0 1 NA FALSE NULL [y]
Then, we may want to set the dimension and attribute names:
= st_set_dimensions(v, names = c("x", "y"))
v names(v) = "elevation"
v## stars object with 2 dimensions and 1 attribute
## attribute(s):
## Min. 1st Qu. Median Mean 3rd Qu. Max.
## elevation 94 108 124 130.1879 150 195
## dimension(s):
## from to offset delta refsys point values x/y
## x 1 61 0 1 NA FALSE NULL [x]
## y 1 87 0 1 NA FALSE NULL [y]
Finally, we set the offset
and delta
of the x and y dimensions, or, other words, where do these axes start from (i.e., origin), and what is their step size (i.e., resolution). The offset
values of 0
(see below), in this case, is arbitrary. The delta
is also arbitrary, but should be equal for both "x"
and "y"
dimensions (unless we want to have asymmetrical pixels). In this case, according to the ?volcano
help page, the matrix represents a 10m by 10m grid. Accordingly, we use delta
values of 10
and -10
so that the coordinate units are “meters”. The delta of the y-axis is negative (!), so that the the values decrease when going to from 1st matrix column to last:
= st_set_dimensions(v, "x", offset = 0, delta = 10)
v = st_set_dimensions(v, "y", offset = 0, delta = -10)
v
v## stars object with 2 dimensions and 1 attribute
## attribute(s):
## Min. 1st Qu. Median Mean 3rd Qu. Max.
## elevation 94 108 124 130.1879 150 195
## dimension(s):
## from to offset delta refsys point values x/y
## x 1 61 0 10 NA NA NULL [x]
## y 1 87 0 -10 NA NA NULL [y]
Compare the output of
plot(v, axes=TRUE)
before and after setting theoffset
anddelta
to see the effect of those settings.
The result is shown in Figure 6.8. Note that we need to use the reset=FALSE
argument whenever we want to have additional layers, such as a contours, in a stars
plot:
plot(v, axes = TRUE, breaks = "equal", col = terrain.colors(100), key.pos = 4, reset = FALSE)
contour(v, add = TRUE)
The fact that the offset
is arbitrary is demonstrated with the following expression, which “shifts” the raster so that the (0, 0) coordinate is in the botton-left rather than top-left corner:
= st_set_dimensions(v, "y", offset = ncol(v) * 10, delta = -10) v
The modified volcano
raster is shown in Figure 6.9.
plot(v, axes = TRUE, breaks = "equal", col = terrain.colors(100), key.pos = 4, reset = FALSE)
contour(v, add = TRUE)
Comparing Figures 6.8 and 6.9, the only thing that has changed are the y-axis coordinates.
6.3.3.2 The Haifa DEM matrix
In the second example, we will recreate the dem.tif
small DEM of Haifa (Figure 5.12), starting from a plain matrix
. Here is the matrix
we start with:
= c(
v NA, NA, NA, NA, NA, NA, NA, 3, 5, 7,
NA, NA, NA, 61, 106, 47, 31, 39, 32, 49,
NA, NA, NA, 9, 132, 254, 233, 253, 199, 179,
NA, NA, NA, 4, 11, 146, 340, 383, 357, 307,
NA, 4, 6, 9, 6, 6, 163, 448, 414, 403,
3, 6, 9, 10, 6, 6, 13, 152, 360, 370,
3, 4, 7, 16, 27, 12, 64, 39, 48, 55
)= matrix(v, nrow = 10, ncol = 7)
m
m## [,1] [,2] [,3] [,4] [,5] [,6] [,7]
## [1,] NA NA NA NA NA 3 3
## [2,] NA NA NA NA 4 6 4
## [3,] NA NA NA NA 6 9 7
## [4,] NA 61 9 4 9 10 16
## [5,] NA 106 132 11 6 6 27
## [6,] NA 47 254 146 6 6 12
## [7,] NA 31 233 340 163 13 64
## [8,] 3 39 253 383 448 152 39
## [9,] 5 32 199 357 414 360 48
## [10,] 7 49 179 307 403 370 55
This time, assuming we know the right spatial reference information, we can create a realistically georeferenced stars
object. To position a matrix or array in geographic space (Section 5.3.1), we need to know the coordinates of the starting point (offset
) and the resolution (delta
) for the "x"
and "y"
dimensions. We also need to know the CRS that the offset
and delta
refer to.
For example, the following code section sets the two offset values (679624
and 3644759
), the resolution (2880
) and the CRS (32636
). Note that the CRS is specified using st_set_crs
and an EPSG code. In this case, the EPSG code 32636
specifies the CRS named “UTM zone 36N”. Again, the y-axis resolution is negative, so that going along the matrix columns translates to decreasing y-axis values.
= st_as_stars(t(m))
s = st_set_dimensions(s, names = c("x", "y"))
s = st_set_dimensions(s, "x", offset = 679624, delta = 2880)
s = st_set_dimensions(s, "y", offset = 3644759, delta = -2880)
s = st_set_crs(s, 32636)
s names(s) = "elevation"
The result is identical to dem.tif
(Figure 5.14), as shown in Figure 6.10:
plot(s, text_values = TRUE, axes = TRUE, breaks = "equal", col = terrain.colors(10))
The effect of transposing the input matrix and modifying the sign of the y-axis delta is summarized in Figure 6.11. The figure demonstrates that only the scenario where delta_y
is negative (while delta_x
is positive) and the input matrix is transposed, ensure that the “print” orientation of the matrix
matches the spatial orientation of the resulting raster.
6.4 Raster algebra
6.4.1 Arithmetic and logical operations on layers
Raster algebra is the application of functions on a cell-by-cell basis, repeatedly for all pixels of one or more overlapping rasters. For example, we can apply the +
function on two overlapping rasters to obtain a new raster, where each pixel value is the sum of the corresponding pixel values from the two inputs (Figure 6.12).
Similarly, we can use any arithmetic (Section 1.3.2) or conditional (Section 1.3.4) operator:
- Arithmetic:
+
,-
,*
,/
- Logical:
<
,<=
,>
,>=
,==
,!=
,!
to make calculations on each pair of overlapping rasters, to get a new raster where each pixel value is the result of the given operation on the overlapping pixels in the input rasters. The operations can also combine rasters and numeric
values, in which case the numeric
value is recycled, as in r>5
.
We can also use functions such as:
- Functions:
is.na
,abs
,round
,ceiling
,floor
,sqrt
,log
,log10
,exp
,cos
,sin
which are applied on an individual raster, transforming each of its pixels, separately.
For the next few examples, let’s create two single-band rasters named x
and y
. Note that we are using round
to transform each of the rasters to rounded values with two decimal places (so that it is more convenient to display text labels):
= r[, 99:101, 202:204, 1, drop = TRUE]
x = r[, 99:101, 200:202, 2, drop = TRUE]
y = round(x, 2)
x = round(y, 2) y
Figure 6.13 shows the two rasters x
and y
:
plot(x, text_values = TRUE, main = "x", col = terrain.colors(5))
plot(y, text_values = TRUE, main = "y", col = terrain.colors(6))
As a first example of raster algebra, we calculate x+y
, where each pixel value is the sum of two corresponding pixels in x
and y
(Figure 6.14):
plot(x, text_values = TRUE, main = "x", col = terrain.colors(5))
plot(y, text_values = TRUE, main = "y", col = terrain.colors(6))
plot(x + y, text_values = TRUE, main = "x+y", col = terrain.colors(5))
Why are two pixels in the bottom-right of
x+y
in Figure 6.14 displayed without any labels?
Here are several other examples of raster algebra: x-y
, x*y
and x+5
. Note that x+5
combines a raster and a numeric
value, rather than two rasters, in which case the numeric
value is recycled (Figure 6.15):
plot(x - y, text_values = TRUE, main = "x-y", col = terrain.colors(5))
plot(x * y, text_values = TRUE, main = "x*y", col = terrain.colors(6))
plot(x + 5, text_values = TRUE, main = "x+5", col = terrain.colors(5))
A logical raster algebra operation produces a logical
raster, a raster where pixel values are TRUE
or FALSE
(or NA
). For example, Figure 6.16 shows the logical rasters x>0.25
, x<y
and is.na(x)
:
plot(x > 0.25, text_values = TRUE, main = "x>0.25", col = terrain.colors(2, rev = TRUE))
plot(x < y, text_values = TRUE, main = "x<y", col = terrain.colors(2, rev = TRUE))
plot(is.na(x), text_values = TRUE, main = "is.na(x)", col = terrain.colors(2, rev = TRUE))
The last three examples produce logical
rasters (Figure 6.16), which we have not encountered so far. In operations where a numeric
representation is required, such as:
- An arithmetic operation
- Saving to a file
logical
raster values TRUE
and FALSE
automatically become 1
and 0
, respectively, similarly to what happens with vectors (Section 2.3.10.1). For example (Figure 6.17):
plot(is.na(x), text_values = TRUE, main = "is.na(x)", col = terrain.colors(2, rev = TRUE))
plot(is.na(x) * 1, text_values = TRUE, main = "is.na(x)*1", col = terrain.colors(2, rev = TRUE))
plot(is.na(x) + 30, text_values = TRUE, main = "is.na(x)+30", col = terrain.colors(2, rev = TRUE))
A logical
raster can be used to assign new values into a subset of raster values. For example, we can use the logical
raster is.na(x)
to replace all NA
values in the raster x
with a new value:
= x
x1 is.na(x1)] = 0.21 x1[
The “before” and “after” images are shown in Figure 6.18:
plot(x, text_values = TRUE, breaks = seq(0.2, 0.3, 0.02), col = terrain.colors(5), main = "Before")
plot(x1, text_values = TRUE, breaks = seq(0.2, 0.3, 0.02), col = terrain.colors(5), main = "After")
How can we replace the
NA
values inx
with the average of all non-missing values?
How can we calculate the proportion of
NA
values inx
?
6.4.2 Landsat image
For the following example, let’s read another multi-band raster file named landsat_04_10_2000.tif
. This is a part of a Landsat-5 satellite image with bands 1-5 and 7, after radiometric and atmospheric corrections. The raster values represent spectral reflectance, therefore all values are between 0 and 1.
= read_stars("landsat_04_10_2000.tif") l
We can assign meaningful layer names according to the spectral range that is captured by each band26:
= c("Blue", "Green", "Red", "NIR", "SWIR1", "SWIR2")
bands = st_set_dimensions(l, "band", values = bands)
l names(l) = "reflectance"
Protting the raster shows the reflectance images for each spectral band (Figure 6.19):
plot(l, breaks = "equal", key.pos = 4)
## downsample set to 1
6.4.3 True color and false color images
An RGB image is an image where the colors are defines based on red, green, and blue intensity per pixel. An RGB image can therefore be constructed from red, green, and blue bands in a multispectral sensor (Figure 6.20), such as the ones in a digital camera or a satellite.
A true color image is an image where the red, green and blue reflectance are red, green and blue colors. A true color image thus simulates the way that we would see the photographed area when looking from above, with the human eye. A false color image is an image where colors are mapped in any different way. A false color image can also include spectral bands that the human eye connot see, such as Near Infra Red (NIR).
True color and false color images can be produced with the plot
function, specifying the red, green and blue bands with the rgb
parameter. For example, in the Landsat image l
, red, green and blue bands are 3
, 2
and 1
, therefore specifying rgb=c(3,2,1)
produces a true color image (Figure 6.21). A different designation, rgb=c(4,3,2)
, produces a commonly used false color image where NIR is mapped to red, red is mapped to green and green is mapped to blue27 (Figure 6.21):
plot(l, rgb = c(3, 2, 1), main = "True color")
plot(l, rgb = c(4, 3, 2), main = "False color")
6.4.4 Calculating NDVI
Multi-spectral images are commonly transformed to single band images using a spectral index. A common example of such an index is the NDVI, which we are familiar with from the raster MOD13A3_2000_2019.tif
(Section 5.3.6). NDVI is defined as the difference between NIR and Red reflectance, divided by their sum (Equation (6.1)).
\[\begin{equation} NDVI=\frac{NIR-Red}{NIR + Red} \tag{6.1} \end{equation}\]
We can calculate an NDVI image based on the red and NIR bands in the Landsat image l
, using raster algebra, as follows:
= l[,,,3, drop = TRUE]
red = l[,,,4, drop = TRUE]
nir = (nir - red) / (nir + red)
ndvi names(ndvi) = "NDVI"
The resulting NDVI image is shown in Figure 6.22:
plot(ndvi, breaks = "equal", col = hcl.colors(11, "Spectral"))
6.5 Raster classification
Raster classification is the process of converting a continuous raster to a discrete one, by giving all pixels in a particular range of values a new uniform value (Figure 6.23).
A raster can be classified, i.e., converted from a continuous raster to a categorical one, by assigning a new value to distinct ranges of the original values. For example, we can reclassify the continuous NDVI raster into two categories:
- Low (\(NDVI\leq0.2\)) get the value of
0
- High (\(NDVI>0.2\)) get the value of
1
Here is how we can do this with R code:
= ndvi
l_rec <= 0.2] = 0
l_rec[ndvi > 0.2] = 1 l_rec[ndvi
The result is shown in Figure 6.2428:
plot(l_rec, col = c("grey90", "darkgreen"))
6.6 Generalizing raster algebra with st_apply
6.6.1 Operating on each pixel
6.6.1.1 Introduction
Suppose that we have a small raster named s
, with two layers:
= r[, 99:101, 202:204, 1:2]
s 1]]
s[[## , , 1
##
## [,1] [,2] [,3]
## [1,] 0.2404 0.2313 0.2452
## [2,] 0.2513 0.2584 0.2564
## [3,] 0.2735 NA NA
##
## , , 2
##
## [,1] [,2] [,3]
## [1,] 0.2236 0.2375 0.2660
## [2,] 0.2680 0.2856 0.2563
## [3,] 0.2852 0.2746 0.2611
and that we would like to add up the two layers, plus a constant value of 10
. We have already seen this is a raster algebra operation that can be achieved with arithmetic operators (Section 6.4.1):
= s[,,,1,drop=TRUE] + s[,,,2,drop=TRUE] + 10
u 1]]
u[[## [,1] [,2] [,3]
## [1,] 10.4640 10.4688 10.5112
## [2,] 10.5193 10.5440 10.5127
## [3,] 10.5587 NA NA
But what if we want to apply a function on three, ten, or a hundred layers? Specifying each and every layer is impractical in such case. For that, we have a more general raster algebra approach using st_apply
. The st_apply
function is very similar to apply
(Section 4.5). It takes an object, the dimension indices we wish to operate on, and a function, then applies the function on each subset along the dimension(s).
For example, the following expression calculates the same raster u
as shown above, using st_apply
:
= st_apply(X = s, MARGIN = 1:2, FUN = function(x) sum(x) + 10)
u 1]]
u[[## [,1] [,2] [,3]
## [1,] 10.4640 10.4688 10.5112
## [2,] 10.5193 10.5440 10.5127
## [3,] 10.5587 NA NA
where function(x) sum(x)+10
is a function applied on the vector of values x
of each pixel.
The FUN
parameter determines the function which is going to be applied on each subset of the chosen dimension, just like in apply
(Section 4.5). In case the dimension we operate on is 1:2
, i.e., “pixels” (Section 5.2.3), the FUN
parameter determines the function which calculates each pixel value in the output raster, given the respective pixel values of the input raster from all layers. The FUN
function needs to accept a vector of any length and return a vector of length 1. As a result, st_apply
returns a single-band raster with the calculated values for each pixel29.
The st_apply
function thus makes it possible to summarize raster dimension(s) properties using various built-in functions, such as mean
, sum
, min
, max
, etc., as well as custom functions (Section 3.3), such as function(x) sum(x)+10
.
6.6.1.2 NDVI
As another example, the expression to calculate NDVI we have seen above (Section 6.4.4):
= l[,,,3, drop = TRUE]
red = l[,,,4, drop = TRUE]
nir = (nir - red) / (nir + red) ndvi
can be replaced with the following analogous expression using st_apply
:
= st_apply(l, 1:2, function(x) (x[4]-x[3])/(x[4]+x[3])) ndvi
6.6.1.3 Pixel means
Calculating pixel means, across all raster layers, is a very common operation with raster time series. The following expression uses st_apply
along with FUN=mean
to calculate a new raster with the average NDVI values (during the period 2000-2019) per pixel, based on the raster r
. The additional na.rm=TRUE
argument is passed to the function (mean
, in this case). This makes the calculation ignore NA
values:
= st_apply(r, 1:2, mean, na.rm = TRUE) s
The resulting average NDVI raster is shown in Figure 6.25:
plot(s, breaks = "equal", col = hcl.colors(11, "Spectral"))
6.6.1.4 Pixel minimum and maximum
In the following example, we use the min
and max
functions to calculate the minimal and maximal NDVI value, respectively, per pixel. In case our raster contains pixels where all values are NA
, such as the case in r
(6.6.1.6), we need to use slightly modified versions of min
and max
to avoid returning Inf
and -Inf
for those pixels:
min(c(NA, NA, NA), na.rm = TRUE)
## [1] Inf
max(c(NA, NA, NA), na.rm = TRUE)
## [1] -Inf
The modified functions can be constructed as follows. In case all values are NA
, the functions return NA
. In case there is at least one non-NA
value, the minimum or maximum is calculated:
= function(x) if(all(is.na(x))) NA else min(x, na.rm = TRUE)
min2 = function(x) if(all(is.na(x))) NA else max(x, na.rm = TRUE) max2
Let’s see if the new functions work as expected:
min2(c(NA, NA, NA, NA, NA))
## [1] NA
min2(c(NA, 24, NA, 20, NA))
## [1] 20
max2(c(NA, NA, NA, NA, NA))
## [1] NA
max2(c(NA, 24, NA, 20, NA))
## [1] 24
Now we can apply min2
and max2
on each pixel, to obtain single-band rasters with the minimum and maximum per pixel:
= st_apply(r, 1:2, min2)
s_min = st_apply(r, 1:2, max2) s_max
The results are shown in Figure 6.26:
plot(s_min, breaks = "equal", col = hcl.colors(11, "Spectral"), key.pos = 4)
plot(s_max, breaks = "equal", col = hcl.colors(11, "Spectral"), key.pos = 4)
6.6.1.5 Pixel amplitudes
We can take the result from Section 6.6.1.4 and further calculate the difference between the maximum and minimum NDVI, i.e., the observed amplitude of NDVI values, in the raster r
. This is yet another example of an arithmetic operator in raster algebra (Section 6.4.1):
= s_max - s_min
s names(s) = "amplitude"
The result is shown in Figure 6.27:
plot(s, breaks = "equal", col = hcl.colors(11, "Spectral"))
6.6.1.6 Pixel NA
proportions
Another practical use case for st_apply
is calculating the proportion of NA
values per pixel:
= st_apply(r, 1:2, function(x) mean(is.na(x)))
s names(s) = "Proportion of NA values"
The result is a raster with values between 0 and 1, where 0 means none of the 233 values of that pixel are NA
, and 1 means that all 233 values are NA
. The raster is shown in Figure 6.28. The second expression uses contour
(Section 5.1.6) to highlight the areas where more than 5% of the pixel values are NA
:
plot(s, breaks = "equal", col = hcl.colors(100, "Spectral"), reset = FALSE)
contour(s, levels = 0.05, add = TRUE)
6.6.2 Operating on each layer
In Section 6.6.1 we have seen examples of applying a function on the value of each pixel, using MARGIN=1:2
. Another useful mode of operation with st_apply
is summarizing the properties of each layer, rather than each pixel. This is achieved with MARGIN=3
. For example, the following expressions calculate the minimum, mean and maximum NDVI value across the entire image per layer (i.e., per month):
= st_apply(r, 3, mean, na.rm = TRUE)
layer_mean = st_apply(r, 3, min, na.rm = TRUE)
layer_min = st_apply(r, 3, max, na.rm = TRUE) layer_max
The resulting stars
objects are one-dimensional. Accordingly, layer_mean[[1]]
, layer_min[[1]]
and layer_max[[1]]
are one-dimensional arrays. One-dimensional arrays are treated as numeric
vectors in most cases. For example, the following expression returns the average NDVI values of the first 10 layers in r
:
1]][1:10]
layer_mean[[## [1] 0.2023428 0.2263248 0.2298939 0.1923323 0.1580042 0.1510594 0.1482469
## [8] 0.1443631 0.1496102 0.1650173
The three resulting time series can therefore be visualized as follows (Figure 6.29):
= st_get_dimension_values(r, "time")
times plot(times, layer_mean[[1]], type = "o", ylim = range(r[[1]], na.rm = TRUE), xlab = "Time", ylab = "NDVI")
lines(times, layer_min[[1]], type = "o", col = "blue")
lines(times, layer_max[[1]], type = "o", col = "red")