Revision c9b2c621c3bff55aaa77646dc1ba7316765cd7e4 authored by Adrian Baddeley on 25 April 2013, 00:00:00 UTC, committed by Gabor Csardi on 25 April 2013, 00:00:00 UTC
1 parent f86606a
Kmulti.Rd
\name{Kmulti}
\alias{Kmulti}
\title{
Marked K-Function
}
\description{
For a marked point pattern,
estimate the multitype \eqn{K} function
which counts the expected number of points of subset \eqn{J}
within a given distance from a typical point in subset \code{I}.
}
\usage{
Kmulti(X, I, J, r=NULL, breaks=NULL, correction, \dots, ratio=FALSE)
}
\arguments{
\item{X}{The observed point pattern,
from which an estimate of the multitype \eqn{K} function
\eqn{K_{IJ}(r)}{KIJ(r)} will be computed.
It must be a marked point pattern.
See under Details.
}
\item{I}{Subset index specifying the points of \code{X}
from which distances are measured. See Details.
}
\item{J}{Subset index specifying the points in \code{X} to which
distances are measured. See Details.
}
\item{r}{numeric vector. The values of the argument \eqn{r}
at which the multitype \eqn{K} function
\eqn{K_{IJ}(r)}{KIJ(r)} should be evaluated.
There is a sensible default.
First-time users are strongly advised not to specify this argument.
See below for important conditions on \eqn{r}.
}
\item{breaks}{An alternative to the argument \code{r}.
Not normally invoked by the user. See the \bold{Details} section.
}
\item{correction}{
A character vector containing any selection of the
options \code{"border"}, \code{"bord.modif"},
\code{"isotropic"}, \code{"Ripley"}, \code{"translate"},
\code{"translation"},
\code{"none"} or \code{"best"}.
It specifies the edge correction(s) to be applied.
}
\item{\dots}{Ignored.}
\item{ratio}{
Logical.
If \code{TRUE}, the numerator and denominator of
each edge-corrected estimate will also be saved,
for use in analysing replicated point patterns.
}
}
\value{
An object of class \code{"fv"} (see \code{\link{fv.object}}).
Essentially a data frame containing numeric columns
\item{r}{the values of the argument \eqn{r}
at which the function \eqn{K_{IJ}(r)}{KIJ(r)} has been estimated
}
\item{theo}{the theoretical value of \eqn{K_{IJ}(r)}{KIJ(r)}
for a marked Poisson process, namely \eqn{\pi r^2}{pi * r^2}
}
together with a column or columns named
\code{"border"}, \code{"bord.modif"},
\code{"iso"} and/or \code{"trans"},
according to the selected edge corrections. These columns contain
estimates of the function \eqn{K_{IJ}(r)}{KIJ(r)}
obtained by the edge corrections named.
If \code{ratio=TRUE} then the return value also has two
attributes called \code{"numerator"} and \code{"denominator"}
which are \code{"fv"} objects
containing the numerators and denominators of each
estimate of \eqn{K(r)}.
}
\details{
The function \code{Kmulti}
generalises \code{\link{Kest}} (for unmarked point
patterns) and \code{\link{Kdot}} and \code{\link{Kcross}} (for
multitype point patterns) to arbitrary marked point patterns.
Suppose \eqn{X_I}{X[I]}, \eqn{X_J}{X[J]} are subsets, possibly
overlapping, of a marked point process.
The multitype \eqn{K} function
is defined so that
\eqn{\lambda_J K_{IJ}(r)}{lambda[J] KIJ(r)} equals the expected number of
additional random points of \eqn{X_J}{X[J]}
within a distance \eqn{r} of a
typical point of \eqn{X_I}{X[I]}.
Here \eqn{\lambda_J}{lambda[J]}
is the intensity of \eqn{X_J}{X[J]}
i.e. the expected number of points of \eqn{X_J}{X[J]} per unit area.
The function \eqn{K_{IJ}}{KIJ} is determined by the
second order moment properties of \eqn{X}.
The argument \code{X} must be a point pattern (object of class
\code{"ppp"}) or any data that are acceptable to \code{\link{as.ppp}}.
The arguments \code{I} and \code{J} specify two subsets of the
point pattern. They may be any type of subset indices, for example,
logical vectors of length equal to \code{npoints(X)},
or integer vectors with entries in the range 1 to
\code{npoints(X)}, or negative integer vectors.
Alternatively, \code{I} and \code{J} may be \bold{functions}
that will be applied to the point pattern \code{X} to obtain
index vectors. If \code{I} is a function, then evaluating
\code{I(X)} should yield a valid subset index. This option
is useful when generating simulation envelopes using
\code{\link{envelope}}.
The argument \code{r} is the vector of values for the
distance \eqn{r} at which \eqn{K_{IJ}(r)}{KIJ(r)} should be evaluated.
It is also used to determine the breakpoints
(in the sense of \code{\link{hist}})
for the computation of histograms of distances.
First-time users would be strongly advised not to specify \code{r}.
However, if it is specified, \code{r} must satisfy \code{r[1] = 0},
and \code{max(r)} must be larger than the radius of the largest disc
contained in the window.
This algorithm assumes that \code{X} can be treated
as a realisation of a stationary (spatially homogeneous)
random spatial point process in the plane, observed through
a bounded window.
The window (which is specified in \code{X} as \code{X$window})
may have arbitrary shape.
Biases due to edge effects are
treated in the same manner as in \code{\link{Kest}}.
The edge corrections implemented here are
\describe{
\item{border}{the border method or
``reduced sample'' estimator (see Ripley, 1988). This is
the least efficient (statistically) and the fastest to compute.
It can be computed for a window of arbitrary shape.
}
\item{isotropic/Ripley}{Ripley's isotropic correction
(see Ripley, 1988; Ohser, 1983).
This is currently implemented only for rectangular windows.
}
\item{translate}{Translation correction (Ohser, 1983).
Implemented for all window geometries.
}
}
The pair correlation function \code{\link{pcf}} can also be applied to the
result of \code{Kmulti}.
}
\references{
Cressie, N.A.C. \emph{Statistics for spatial data}.
John Wiley and Sons, 1991.
Diggle, P.J. \emph{Statistical analysis of spatial point patterns}.
Academic Press, 1983.
Diggle, P. J. (1986).
Displaced amacrine cells in the retina of a
rabbit : analysis of a bivariate spatial point pattern.
\emph{J. Neurosci. Meth.} \bold{18}, 115--125.
Harkness, R.D and Isham, V. (1983)
A bivariate spatial point pattern of ants' nests.
\emph{Applied Statistics} \bold{32}, 293--303
Lotwick, H. W. and Silverman, B. W. (1982).
Methods for analysing spatial processes of several types of points.
\emph{J. Royal Statist. Soc. Ser. B} \bold{44}, 406--413.
Ripley, B.D. \emph{Statistical inference for spatial processes}.
Cambridge University Press, 1988.
Stoyan, D, Kendall, W.S. and Mecke, J.
\emph{Stochastic geometry and its applications}.
2nd edition. Springer Verlag, 1995.
Van Lieshout, M.N.M. and Baddeley, A.J. (1999)
Indices of dependence between types in multivariate point patterns.
\emph{Scandinavian Journal of Statistics} \bold{26}, 511--532.
}
\section{Warnings}{
The function \eqn{K_{IJ}}{KIJ} is not necessarily differentiable.
The border correction (reduced sample) estimator of
\eqn{K_{IJ}}{KIJ} used here is pointwise approximately
unbiased, but need not be a nondecreasing function of \eqn{r},
while the true \eqn{K_{IJ}}{KIJ} must be nondecreasing.
}
\seealso{
\code{\link{Kcross}},
\code{\link{Kdot}},
\code{\link{Kest}},
\code{\link{pcf}}
}
\examples{
# Longleaf Pine data: marks represent diameter
\testonly{
longleaf <- longleaf[seq(1,npoints(longleaf), by=50), ]
}
K <- Kmulti(longleaf, longleaf$marks <= 15, longleaf$marks >= 25)
plot(K)
# functions determining subsets
f1 <- function(X) { marks(X) <= 15 }
f2 <- function(X) { marks(X) >= 15 }
K <- Kmulti(longleaf, f1, f2)
\testonly{
rm(longleaf)
}
}
\author{Adrian Baddeley
\email{Adrian.Baddeley@csiro.au}
\url{http://www.maths.uwa.edu.au/~adrian/}
and Rolf Turner
\email{r.turner@auckland.ac.nz}
}
\keyword{spatial}
\keyword{nonparametric}
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