spherical.sd: Spherical Variance or Standard Deviation of Surface
In jeffreyevans/spatialEco: Spatial Analysis and Modelling Utilities
spherical.sd R Documentation
Spherical Variance or Standard Deviation of Surface
Description
Derives the spherical standard deviation of a raster surface
Usage
spherical.sd(r, d, variance = FALSE, ...)
Arguments
r
A terra SpatRaster class object
d
Size of focal window or a matrix to use in focal function
variance
(FALSE|TRUE) Output spherical variance rather than standard deviation
...
Additional arguments passed to terra:app (can write raster to disk here)
Details
Surface variability using spherical variance/standard deviation.
The variation can be assessed using the spherical standard deviation of the normal
direction within a local neighborhood. This is found by expressing the normal
directions on the surfaces cells in terms of their displacements in a Cartesian (x,y,z)
coordinate system. Averaging the x-coordinates, y-coordinates, and z-coordinates
separately gives a vector (xb, yb, zb) pointing in the direction of the average
normal. This vector will be shorter when there is more variation of the normals and
it will be longest–equal to unity–when there is no variation. Its squared length
is (by the Pythagorean theorem) given by: R^2 = xb^2 + yb^2 + zb^2
where; x = cos(aspect) * sin(slope) and xb = nXn focal mean of x
y = sin(aspect) * sin(slope) and yb = nXn focal mean of y
z = cos(slope) and zb = nXn focal mean of z
The slope and aspect values are expected to be in radians.
The value of (1 - R^2), which will lie between 0 and 1, is the spherical variance.
and it's square root can be considered the spherical standard deviation.
Value
A terra SpatRaster class object of the spherical standard deviation
Author(s)
Jeffrey S. Evans <jeffrey_evans<at>tnc.org>
See Also
app for details on ... arguments
Examples
library(terra)
elev <- rast(system.file("extdata/elev.tif", package="spatialEco"))
ssd <- spherical.sd(elev, d=5)
slope <- terrain(elev, v='slope')
aspect <- terrain(elev, v='aspect')
hill <- shade(slope, aspect, 40, 270)
plot(hill, col=grey(0:100/100), legend=FALSE,
main='terrain spherical standard deviation')
plot(ssd, col=rainbow(25, alpha=0.35), add=TRUE)
jeffreyevans/spatialEco documentation built on April 4, 2024, 10:53 a.m.
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| spherical.sd | R Documentation |
Spherical Variance or Standard Deviation of Surface
Description
Derives the spherical standard deviation of a raster surface
Usage
spherical.sd(r, d, variance = FALSE, ...)
Arguments
r |
A terra SpatRaster class object |
d |
Size of focal window or a matrix to use in focal function |
variance |
(FALSE|TRUE) Output spherical variance rather than standard deviation |
... |
Additional arguments passed to terra:app (can write raster to disk here) |
Details
Surface variability using spherical variance/standard deviation. The variation can be assessed using the spherical standard deviation of the normal direction within a local neighborhood. This is found by expressing the normal directions on the surfaces cells in terms of their displacements in a Cartesian (x,y,z) coordinate system. Averaging the x-coordinates, y-coordinates, and z-coordinates separately gives a vector (xb, yb, zb) pointing in the direction of the average normal. This vector will be shorter when there is more variation of the normals and it will be longest–equal to unity–when there is no variation. Its squared length is (by the Pythagorean theorem) given by: R^2 = xb^2 + yb^2 + zb^2 where; x = cos(aspect) * sin(slope) and xb = nXn focal mean of x y = sin(aspect) * sin(slope) and yb = nXn focal mean of y z = cos(slope) and zb = nXn focal mean of z
The slope and aspect values are expected to be in radians. The value of (1 - R^2), which will lie between 0 and 1, is the spherical variance. and it's square root can be considered the spherical standard deviation.
Value
A terra SpatRaster class object of the spherical standard deviation
Author(s)
Jeffrey S. Evans <jeffrey_evans<at>tnc.org>
See Also
app for details on ... arguments
Examples
library(terra)
elev <- rast(system.file("extdata/elev.tif", package="spatialEco"))
ssd <- spherical.sd(elev, d=5)
slope <- terrain(elev, v='slope')
aspect <- terrain(elev, v='aspect')
hill <- shade(slope, aspect, 40, 270)
plot(hill, col=grey(0:100/100), legend=FALSE,
main='terrain spherical standard deviation')
plot(ssd, col=rainbow(25, alpha=0.35), add=TRUE)
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Note that we can't provide technical support on individual packages. You should contact the package authors for that.
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