krfun: Multiscale second-order neighbourhood analysis of a...
In ads: Spatial Point Patterns Analysis
krfun R Documentation
Multiscale second-order neighbourhood analysis of a multivariate spatial point pattern using Rao quadratic entropy
Description
Computes distance-dependent estimates of Rao's quadratic entropy from a multivariate spatial point pattern
in a simple (rectangular or circular) or complex sampling window. Computes optionally local confidence limits of the functions
under the null hypothesis of either a random labelling or a species equivalence (see Details).
Usage
krfun(p, upto, by, nsim=0, dis = NULL, H0 = c("rl", "se"), alpha = 0.01)
Arguments
p
a "spp" object defining a spatial point pattern in a given sampling window (see spp).
upto
maximum radius of the sample circles (see Details).
by
interval length between successive sample circles radii (see Details).
nsim
number of Monte Carlo simulations to estimate local confidence limits of the null hypothesis of a random allocation of species labels (see Details).
By default nsim = 0, so that no confidence limits are computed.
dis
(optional) a "dist" object defining Euclidean distances between species. By default dis = NULL so that species are considered equidistant.
H0
one of c("rl","se") to select either the null hypothesis of random labelling (H0 = "rl") or species equivalence (H0 = "se") (see Details). By default, the null hypothesis is random labelling.
alpha
if nsim>0, significant level of the confidence limits. By default \alpha = 0.01.
Details
Function krfun computes distance-dependent functions of Rao (1982) quadratic entropy (see divc in package ade4).
For a multivariate point pattern consisting of S species with intensity \lambdap, such functions can be estimated from the bivariate Kpq-functions between each pair of different species p and q.
Function krfun is thus a simple wrapper function of k12fun and kfun, standardized by Rao diversity coefficient (Pelissier & Goreaud 2014):
Kr(r) = sum(\lambda p * \lambda q * Kpq(r)*dpq) / (\lambda * \lambda * K(r) * HD).
gr(r) = sum(\lambda p * \lambda q * gpq(r)*dpq) / (\lambda * \lambda * g(r) * HD).
where dpq is the distance between species p and q defined by matrix dis, typically a taxonomic, phylogenetic or functional distance, and HD=sum(Np*Nq*dpq/(N(N - 1))) is the unbiased version of Rao diversity coefficient (see Shimatani 2001). When dis = NULL, species are considered each other equidistant and krfun returns the same results than ksfun.
The program introduces an edge effect correction term according to the method proposed by Ripley (1977)
and extended to circular and complex sampling windows by Goreaud & Pelissier (1999).
Theoretical values under the null hypothesis of either random labelling or species equivalence as well as local Monte Carlo confidence limits and p-values of departure from the null hypothesis (Besag & Diggle 1977) are estimated at each distance r.
The random labelling hypothesis (H0 = "rl") is tested by reallocating species labels at random among all points of the pattern, keeping the point locations unchanged, so that expectations of gr(r) and Kr(r) are 1 for all r.
The species equivalence hypothesis (H0 = "se") is tested by randomizing the between-species distances, keeping the point locations and distribution of species labels unchanged. The theoretical expectations of gr(r) and Kr(r) are thus gs(r) and Ks(r), respectively (see ksfun).
Value
A list of class "fads" with essentially the following components:
r
a vector of regularly spaced out distances (seq(by,upto,by)).
gr
a data frame containing values of the function gr(r).
kr
a data frame containing values of the function Kr(r).
Each component except r is a data frame with the following variables:
obs
a vector of estimated values for the observed point pattern.
theo
a vector of theoretical values expected under the selected null hypothesis.
sup
(optional) if nsim>0 a vector of the upper local confidence limits of a random distribution of the selected null hypothesis at a significant level \alpha.
inf
(optional) if nsim>0 a vector of the lower local confidence limits of a random distribution of the selected null hypothesis at a significant level \alpha.
pval
(optional) if nsim>0 a vector of local p-values of departure from the selected null hypothesis.
Note
There are printing and plotting methods for "fads" objects.
Author(s)
References
Rao, C.R. 1982. Diversity and dissimilarity coefficient: a unified approach. Theoretical Population Biology, 21:24-43.
Shimatani, K. 2001. On the measurement of species diversity incorporating species differences. Oikos, 93, 135-147.
Goreaud F. & Pelissier R. 1999. On explicit formulas of edge effect correction for Ripley's K-function. Journal of Vegetation Science, 10:433-438.
Ripley B.D. 1977. Modelling spatial patterns. Journal of the Royal Statistical Society B, 39:172-192.
Pelissier, R. & Goreaud, F. 2014. ads package for R: A fast unbiased implementation of the k-function family for studying spatial point patterns in irregular-shaped sampling windows. Journal of Statistical Software, in press.
See Also
plot.fads,
spp,
ksfun,
kdfun,
divc.
Examples
data(Paracou15)
P15<-Paracou15
## Not run: spatial point pattern in a rectangle sampling window of size 125 x 125
swmr <- spp(P15$trees, win = c(175, 175, 250, 250), marks = P15$species)
## Not run: testing the random labeling hypothesis
krwmr.rl <- krfun(swmr, dis = P15$spdist, H0 = "rl", 25, 2, 50)
## Not run: running more simulations is slow
krwmr.rl <- krfun(swmr, dis = P15$spdist, H0 = "rl", 25, 2, 500)
plot(krwmr.rl)
## Not run: testing the species equivalence hypothesis
krwmr.se <- krfun(swmr, dis = P15$spdist, H0 = "se", 25, 2, 50)
## Not run: running more simulations is slow
krwmr.se <- krfun(swmr, dis = P15$spdist, H0 = "se", 25, 2, 500)
plot(krwmr.se)
## Not run: spatial point pattern in a circle with radius 50 centred on (125,125)
swmc <- spp(P15$trees, win = c(125,125,50), marks = P15$species)
krwmc <- krfun(swmc, dis = P15$spdist, H0 = "rl", 25, 2, 100)
## Not run: running more simulations is slow
krwmc <- krfun(swmc, dis = P15$spdist, H0 = "rl", 25, 2, 500)
plot(krwmc)
## Not run: spatial point pattern in a complex sampling window
swrt <- spp(P15$trees, win = c(125,125,250,250), tri = P15$tri, marks = P15$species)
krwrt <- krfun(swrt, dis = P15$spdist, H0 = "rl", 25, 2)
## Not run: running simulations is slow
krwrt <- krfun(swrt, dis = P15$spdist, H0 = "rl", 25, 2, 500)
plot(krwrt)
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| krfun | R Documentation |
Multiscale second-order neighbourhood analysis of a multivariate spatial point pattern using Rao quadratic entropy
Description
Computes distance-dependent estimates of Rao's quadratic entropy from a multivariate spatial point pattern in a simple (rectangular or circular) or complex sampling window. Computes optionally local confidence limits of the functions under the null hypothesis of either a random labelling or a species equivalence (see Details).
Usage
krfun(p, upto, by, nsim=0, dis = NULL, H0 = c("rl", "se"), alpha = 0.01)
Arguments
p |
a |
upto |
maximum radius of the sample circles (see Details). |
by |
interval length between successive sample circles radii (see Details). |
nsim |
number of Monte Carlo simulations to estimate local confidence limits of the null hypothesis of a random allocation of species labels (see Details).
By default |
dis |
(optional) a |
H0 |
one of c("rl","se") to select either the null hypothesis of random labelling (H0 = "rl") or species equivalence (H0 = "se") (see Details). By default, the null hypothesis is random labelling. |
alpha |
if |
Details
Function krfun computes distance-dependent functions of Rao (1982) quadratic entropy (see divc in package ade4).
For a multivariate point pattern consisting of S species with intensity \lambdap, such functions can be estimated from the bivariate Kpq-functions between each pair of different species p and q.
Function krfun is thus a simple wrapper function of k12fun and kfun, standardized by Rao diversity coefficient (Pelissier & Goreaud 2014):
Kr(r) = sum(\lambda p * \lambda q * Kpq(r)*dpq) / (\lambda * \lambda * K(r) * HD).
gr(r) = sum(\lambda p * \lambda q * gpq(r)*dpq) / (\lambda * \lambda * g(r) * HD).
where dpq is the distance between species p and q defined by matrix dis, typically a taxonomic, phylogenetic or functional distance, and HD=sum(Np*Nq*dpq/(N(N - 1))) is the unbiased version of Rao diversity coefficient (see Shimatani 2001). When dis = NULL, species are considered each other equidistant and krfun returns the same results than ksfun.
The program introduces an edge effect correction term according to the method proposed by Ripley (1977)
and extended to circular and complex sampling windows by Goreaud & Pelissier (1999).
Theoretical values under the null hypothesis of either random labelling or species equivalence as well as local Monte Carlo confidence limits and p-values of departure from the null hypothesis (Besag & Diggle 1977) are estimated at each distance r.
The random labelling hypothesis (H0 = "rl") is tested by reallocating species labels at random among all points of the pattern, keeping the point locations unchanged, so that expectations of gr(r) and Kr(r) are 1 for all r.
The species equivalence hypothesis (H0 = "se") is tested by randomizing the between-species distances, keeping the point locations and distribution of species labels unchanged. The theoretical expectations of gr(r) and Kr(r) are thus gs(r) and Ks(r), respectively (see ksfun).
Value
A list of class "fads" with essentially the following components:
r |
a vector of regularly spaced out distances ( |
gr |
a data frame containing values of the function |
kr |
a data frame containing values of the function |
Each component except r is a data frame with the following variables:
obs |
a vector of estimated values for the observed point pattern. |
theo |
a vector of theoretical values expected under the selected null hypothesis. |
sup |
(optional) if |
inf |
(optional) if |
pval |
(optional) if |
Note
There are printing and plotting methods for "fads" objects.
Author(s)
References
Rao, C.R. 1982. Diversity and dissimilarity coefficient: a unified approach. Theoretical Population Biology, 21:24-43.
Shimatani, K. 2001. On the measurement of species diversity incorporating species differences. Oikos, 93, 135-147.
Goreaud F. & Pelissier R. 1999. On explicit formulas of edge effect correction for Ripley's K-function. Journal of Vegetation Science, 10:433-438.
Ripley B.D. 1977. Modelling spatial patterns. Journal of the Royal Statistical Society B, 39:172-192.
Pelissier, R. & Goreaud, F. 2014. ads package for R: A fast unbiased implementation of the k-function family for studying spatial point patterns in irregular-shaped sampling windows. Journal of Statistical Software, in press.
See Also
plot.fads,
spp,
ksfun,
kdfun,
divc.
Examples
data(Paracou15)
P15<-Paracou15
## Not run: spatial point pattern in a rectangle sampling window of size 125 x 125
swmr <- spp(P15$trees, win = c(175, 175, 250, 250), marks = P15$species)
## Not run: testing the random labeling hypothesis
krwmr.rl <- krfun(swmr, dis = P15$spdist, H0 = "rl", 25, 2, 50)
## Not run: running more simulations is slow
krwmr.rl <- krfun(swmr, dis = P15$spdist, H0 = "rl", 25, 2, 500)
plot(krwmr.rl)
## Not run: testing the species equivalence hypothesis
krwmr.se <- krfun(swmr, dis = P15$spdist, H0 = "se", 25, 2, 50)
## Not run: running more simulations is slow
krwmr.se <- krfun(swmr, dis = P15$spdist, H0 = "se", 25, 2, 500)
plot(krwmr.se)
## Not run: spatial point pattern in a circle with radius 50 centred on (125,125)
swmc <- spp(P15$trees, win = c(125,125,50), marks = P15$species)
krwmc <- krfun(swmc, dis = P15$spdist, H0 = "rl", 25, 2, 100)
## Not run: running more simulations is slow
krwmc <- krfun(swmc, dis = P15$spdist, H0 = "rl", 25, 2, 500)
plot(krwmc)
## Not run: spatial point pattern in a complex sampling window
swrt <- spp(P15$trees, win = c(125,125,250,250), tri = P15$tri, marks = P15$species)
krwrt <- krfun(swrt, dis = P15$spdist, H0 = "rl", 25, 2)
## Not run: running simulations is slow
krwrt <- krfun(swrt, dis = P15$spdist, H0 = "rl", 25, 2, 500)
plot(krwrt)
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