Plot a spatially sampled function object.
# S3 method for ssf
plot(x, …,
how = c("smoothed", "nearest", "points"),
style = c("image", "contour", "imagecontour"),
sigma = NULL, contourargs=list())# S3 method for ssf
image(x, …)
# S3 method for ssf
contour(x, ..., main, sigma = NULL)
Spatially sampled function (object of class "ssf"
).
Arguments passed to image.default
or
plot.ppp
to control the plot.
Character string determining whether to display the
function values at the data points (how="points"
),
a smoothed interpolation of the function
(how="smoothed"
), or the function value at the
nearest data point (how="nearest"
).
Character string indicating whether to plot the smoothed function as a colour image, a contour map, or both.
Arguments passed to contour.default
to control the contours, if style="contour"
or
style="imagecontour"
.
Smoothing bandwidth for smooth interpolation.
Optional main title for the plot.
NULL
.
These are methods for the generic
plot
,
image
and
contour
for the class "ssf"
.
An object of class "ssf"
represents a
function (real- or vector-valued) that has been
sampled at a finite set of points.
For plot.ssf
there are three types of display.
If how="points"
the exact function values
will be displayed as circles centred at the locations where they
were computed. If how="smoothed"
(the default) these
values will be kernel-smoothed using Smooth.ppp
and displayed as a pixel image.
If how="nearest"
the values will be interpolated
by nearest neighbour interpolation using nnmark
and displayed as a pixel image.
For image.ssf
and contour.ssf
the values are
kernel-smoothed before being displayed.
Baddeley, A. (2017) Local composite likelihood for spatial point processes. Spatial Statistics 22, 261--295.
Baddeley, A., Rubak, E. and Turner, R. (2015) Spatial Point Patterns: Methodology and Applications with R. Chapman and Hall/CRC Press.
# NOT RUN {
a <- ssf(cells, nndist(cells, k=1:3))
plot(a, how="points")
plot(a, how="smoothed")
plot(a, how="nearest")
# }
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