Computes an estimate of the inhomogeneous linear pair correlation function for a point pattern on a linear network.
linearpcfinhom(X, lambda=NULL, r=NULL, ..., correction="Ang",
normalise=TRUE, normpower=1,
update = TRUE, leaveoneout = TRUE,
ratio = FALSE)Point pattern on linear network (object of class "lpp").
Intensity values for the point pattern. Either a numeric vector,
a function, a pixel image (object of class "im") or
a fitted point process model (object of class "ppm"
or "lppm").
Optional. Numeric vector of values of the function argument \(r\). There is a sensible default.
Arguments passed to density.default
to control the smoothing.
Geometry correction.
Either "none" or "Ang". See Details.
Logical. If TRUE (the default), the denominator of the estimator is
data-dependent (equal to the sum of the reciprocal intensities at the data
points, raised to normpower), which reduces the sampling variability.
If FALSE, the denominator is the length of the network.
Integer (usually either 1 or 2).
Normalisation power. See explanation in linearKinhom.
Logical value indicating what to do when lambda is a fitted model
(class "lppm" or "ppm").
If update=TRUE (the default),
the model will first be refitted to the data X
(using update.lppm or update.ppm)
before the fitted intensity is computed.
If update=FALSE, the fitted intensity of the
model will be computed without re-fitting it to X.
Logical value (passed to fitted.lppm or
fitted.ppm) specifying whether to use a
leave-one-out rule when calculating the intensity,
when lambda is a fitted model.
Supported only when update=TRUE.
Logical.
If TRUE, the numerator and denominator of
each estimate will also be saved,
for use in analysing replicated point patterns.
Function value table (object of class "fv").
If ratio=TRUE then the return value also has two
attributes called "numerator" and "denominator"
which are "fv" objects
containing the numerators and denominators of each
estimate of \(g(r)\).
This command computes the inhomogeneous version of the linear pair correlation function from point pattern data on a linear network.
If lambda = NULL the result is equivalent to the
homogeneous pair correlation function linearpcf.
If lambda is given, then it is expected to provide estimated values
of the intensity of the point process at each point of X.
The argument lambda may be a numeric vector (of length equal to
the number of points in X), or a function(x,y) that will be
evaluated at the points of X to yield numeric values,
or a pixel image (object of class "im") or a fitted point
process model (object of class "ppm" or "lppm").
If lambda is a fitted point process model,
the default behaviour is to update the model by re-fitting it to
the data, before computing the fitted intensity.
This can be disabled by setting update=FALSE.
If correction="none", the calculations do not include
any correction for the geometry of the linear network.
If correction="Ang", the pair counts are weighted using
Ang's correction (Ang, 2010).
The bandwidth for smoothing the pairwise distances
is determined by arguments …
passed to density.default, mainly the arguments
bw and adjust. The default is
to choose the bandwidth by Silverman's rule of thumb
bw="nrd0" explained in density.default.
Ang, Q.W. (2010) Statistical methodology for spatial point patterns on a linear network. MSc thesis, University of Western Australia.
Ang, Q.W., Baddeley, A. and Nair, G. (2012) Geometrically corrected second-order analysis of events on a linear network, with applications to ecology and criminology. Scandinavian Journal of Statistics 39, 591--617.
Okabe, A. and Yamada, I. (2001) The K-function method on a network and its computational implementation. Geographical Analysis 33, 271-290.
# NOT RUN {
data(simplenet)
X <- rpoislpp(5, simplenet)
fit <- lppm(X ~x)
K <- linearpcfinhom(X, lambda=fit)
plot(K)
# }
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