localKinhom(X, lambda, ...,
correction = "Ripley", verbose = TRUE, rvalue=NULL,
sigma = NULL, varcov = NULL)
localLinhom(X, lambda, ...,
correction = "Ripley", verbose = TRUE, rvalue=NULL,
sigma = NULL, varcov = NULL)
"ppp"
).X
,
a pixel image (object of class "im"
) giving the
intensity values at all locatiolambda
is present.
Passed to density.ppp
if lambda
is omitted."none"
, "translate"
, "Ripley"
,
"translation"
, "isotropic"
or "best"
.
Only one correction may be specdensity.ppp
to control
the kernel smoothing procedure for estimating lambda
,
if lambda
is missing.rvalue
is given, the result is a numeric vector
of length equal to the number of points in the point pattern. If rvalue
is absent, the result is
an object of class "fv"
, see fv.object
,
which can be plotted directly using plot.fv
.
Essentially a data frame containing columns
i
corresponds to the i
th point.
The last two columns contain the r
and theo
values.localKinhom
and localLinhom
are inhomogeneous or weighted versions of the
neighbourhood density function implemented in
localK
and localL
. Given a spatial point pattern X
, the
inhomogeneous neighbourhood density function
$L_i(r)$ associated with the $i$th point
in X
is computed by
$$L_i(r) = \sqrt{\frac 1 \pi \sum_j \frac{e_{ij}}{\lambda_j}}$$
where the sum is over all points $j \neq i$ that lie
within a distance $r$ of the $i$th point,
$\lambda_j$ is the estimated intensity of the
point pattern at the point $j$,
and $e_{ij}$ is an edge correction
term (as described in Kest
).
The value of $L_i(r)$ can also be interpreted as one
of the summands that contributes to the global estimate of the
inhomogeneous L function (see Linhom
).
By default, the function $L_i(r)$ or
$K_i(r)$ is computed for a range of $r$ values
for each point $i$. The results are stored as a function value
table (object of class "fv"
) with a column of the table
containing the function estimates for each point of the pattern
X
.
Alternatively, if the argument rvalue
is given, and it is a
single number, then the function will only be computed for this value
of $r$, and the results will be returned as a numeric vector,
with one entry of the vector for each point of the pattern X
.
Kinhom
,
Linhom
,
localK
,
localL
.data(ponderosa)
X <- ponderosa
# compute all the local L functions
L <- localLinhom(X)
# plot all the local L functions against r
plot(L, main="local L functions for ponderosa", legend=FALSE)
# plot only the local L function for point number 7
plot(L, iso007 ~ r)
# compute the values of L(r) for r = 12 metres
L12 <- localL(X, rvalue=12)
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