localpcf
computes the contribution, from each individual
data point in a point pattern X
, to the
empirical pair correlation function of X
.
These contributions are sometimes known as LISA (local indicator
of spatial association) functions based on pair correlation.
localpcfinhom
computes the corresponding contribution
to the inhomogeneous empirical pair correlation function of X
.
Given a spatial point pattern X
, the local pcf
\(g_i(r)\) associated with the \(i\)th point
in X
is computed by
$$
g_i(r) = \frac a {2 \pi n} \sum_j k(d_{i,j} - r)
$$
where the sum is over all points \(j \neq i\),
\(a\) is the area of the observation window, \(n\) is the number
of points in X
, and \(d_{ij}\) is the distance
between points i
and j
. Here k
is the
Epanechnikov kernel,
$$
k(t) = \frac 3 { 4\delta} \max(0, 1 - \frac{t^2}{\delta^2}).
$$
Edge correction is performed using the border method
(for the sake of computational efficiency):
the estimate \(g_i(r)\) is set to NA
if
\(r > b_i\), where \(b_i\)
is the distance from point \(i\) to the boundary of the
observation window.
The smoothing bandwidth \(\delta\) may be specified.
If not, it is chosen by Stoyan's rule of thumb
\(\delta = c/\hat\lambda\)
where \(\hat\lambda = n/a\) is the estimated intensity
and \(c\) is a constant, usually taken to be 0.15.
The value of \(c\) is controlled by the argument stoyan
.
For localpcfinhom
, the optional argument lambda
specifies the values of the estimated intensity function.
If lambda
is given, it should be either a
numeric vector giving the intensity values
at the points of the pattern X
,
a pixel image (object of class "im"
) giving the
intensity values at all locations, a fitted point process model
(object of class "ppm"
) or a function(x,y)
which
can be evaluated to give the intensity value at any location.
If lambda
is not given, then it will be estimated
using a leave-one-out kernel density smoother as described
in pcfinhom
.