spsample.prob: Estimate occurrence probabilities of a sampling plan (points)
In landmap: Automated Spatial Prediction using Ensemble Machine Learning
Description
Usage
Arguments
Value
Note
Author(s)
References
Examples
Description
Estimates occurrence probabilities as an average between the kernel density estimation (spreading of points in geographical space) and MaxLike analysis (spreading of points in feature space). The output 'iprob' indicates whether the sampling plan has systematically missed some important locations / features, and can be used as an input for modelling (e.g. as weights for regression modeling).
Usage
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## S4 method for signature 'SpatialPoints,SpatialPixelsDataFrame'
spsample.prob(observations, covariates, quant.nndist = 0.95, n.sigma, ...)
Arguments
observations
SpatialPoints.
covariates
SpatialPixelsDataFrame.
quant.nndist
quantile used for the threshold distance.
n.sigma
sigma parameter for density estimation.
...
optional arguments.
Value
Returns a list of objects where 'iprob' ("SpatialPixelsDataFrame") is the map showing the estimated occurrence probabilities.
Note
Occurrence probabilities for geographical space are derived using kernel density estimator. The sampling intensities are converted to probabilities by deviding the sampling intensity by the maximum sampling intensity for the study area (Baddeley, 2008). The occurrence probabilities for feature space are determined using MaxLike algorithm (Royle et al., 2012; doi: 10.1111/j.2041-210X.2011.00182.x). The lower the average occurrence probability for the whole study area, the lower the representation efficiency of a sampling plan.
MaxLike function might fail to produce predictions (e.g. if not at least one continuous covariate is provided and if the optim function is not able to find the global optima) in which case an error message is generated. Running Principal Component analysis i.e. standardizing the covariates prior to running spsample.prob is, thus, highly recommended.
This function can be time consuming for large grids.
Author(s)
References
Baddeley, A. (2008) Analysing spatial point patterns in R. Technical report, CSIRO Australia. Version 4.
Royle, J.A., Chandler, R.B., Yackulic, C. and J. D. Nichols. (2012) Likelihood analysis of species occurrence probability from presence-only data for modelling species distributions. Methods in Ecology and Evolution. doi: 10.1111/j.2041-210X.2011.00182.x
Examples
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if(requireNamespace("plotKML", quietly = TRUE) &
requireNamespace("maxlike", quietly = TRUE) &
requireNamespace("spatstat", quietly = TRUE) ){
library(plotKML)
library(maxlike)
library(spatstat)
library(maptools)
data(eberg)
data(eberg_grid)
## existing sampling plan:
sel <- runif(nrow(eberg)) < .2
eberg.xy <- eberg[sel,c("X","Y")]
coordinates(eberg.xy) <- ~X+Y
proj4string(eberg.xy) <- CRS("+init=epsg:31467")
## covariates:
gridded(eberg_grid) <- ~x+y
proj4string(eberg_grid) <- CRS("+init=epsg:31467")
## convert to continuous independent covariates:
formulaString <- ~ PRMGEO6+DEMSRT6+TWISRT6+TIRAST6
eberg_spc <- spc(eberg_grid, formulaString)
## Not run:
## derive occurrence probability:
covs <- eberg_spc@predicted[1:8]
iprob <- spsample.prob(eberg.xy, covs)
## Note: obvious omission areas:
hist(iprob[[1]]@data[,1], col="gray")
## compare with random sampling:
rnd <- spsample(eberg_grid, type="random",
n=length(iprob[["observations"]]))
iprob2 <- spsample.prob(rnd, covs)
## compare the two next to each other:
op <- par(mfrow=c(1,2))
plot(raster(iprob[[1]]), zlim=c(0,1), col=SAGA_pal[[1]])
points(iprob[["observations"]])
plot(raster(iprob2[[1]]), zlim=c(0,1), col=SAGA_pal[[1]])
points(iprob2[["observations"]])
par(op)
while (!is.null(dev.list())) dev.off()
## fit a weighted lm:
eberg.xy <- eberg[sel,c("SNDMHT_A","X","Y")]
coordinates(eberg.xy) <- ~X+Y
proj4string(eberg.xy) <- CRS("+init=epsg:31467")
eberg.xy$iprob <- over(eberg.xy, iprob[[1]])$iprob
eberg.xy@data <- cbind(eberg.xy@data, over(eberg.xy, covs))
fs <- as.formula(paste("SNDMHT_A ~ ",
paste(names(covs), collapse="+")))
## the lower the occurrence probability, the higher the weight:
w <- 1/eberg.xy$iprob
m <- lm(fs, eberg.xy, weights=w)
summary(m)
## compare to standard lm:
m0 <- lm(fs, eberg.xy)
summary(m)$adj.r.squared
summary(m0)$adj.r.squared
## End(Not run)
}
landmap documentation built on Oct. 14, 2021, 5:24 p.m.
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Description Usage Arguments Value Note Author(s) References Examples
Description
Estimates occurrence probabilities as an average between the kernel density estimation (spreading of points in geographical space) and MaxLike analysis (spreading of points in feature space). The output 'iprob' indicates whether the sampling plan has systematically missed some important locations / features, and can be used as an input for modelling (e.g. as weights for regression modeling).
Usage
1 2 | ## S4 method for signature 'SpatialPoints,SpatialPixelsDataFrame'
spsample.prob(observations, covariates, quant.nndist = 0.95, n.sigma, ...)
|
Arguments
observations |
SpatialPoints. |
covariates |
SpatialPixelsDataFrame. |
quant.nndist |
quantile used for the threshold distance. |
n.sigma |
sigma parameter for density estimation. |
... |
optional arguments. |
Value
Returns a list of objects where 'iprob' ("SpatialPixelsDataFrame") is the map showing the estimated occurrence probabilities.
Note
Occurrence probabilities for geographical space are derived using kernel density estimator. The sampling intensities are converted to probabilities by deviding the sampling intensity by the maximum sampling intensity for the study area (Baddeley, 2008). The occurrence probabilities for feature space are determined using MaxLike algorithm (Royle et al., 2012; doi: 10.1111/j.2041-210X.2011.00182.x). The lower the average occurrence probability for the whole study area, the lower the representation efficiency of a sampling plan.
MaxLike function might fail to produce predictions (e.g. if not at least one continuous covariate is provided and if the optim function is not able to find the global optima) in which case an error message is generated. Running Principal Component analysis i.e. standardizing the covariates prior to running spsample.prob is, thus, highly recommended.
This function can be time consuming for large grids.
Author(s)
References
Baddeley, A. (2008) Analysing spatial point patterns in R. Technical report, CSIRO Australia. Version 4.
Royle, J.A., Chandler, R.B., Yackulic, C. and J. D. Nichols. (2012) Likelihood analysis of species occurrence probability from presence-only data for modelling species distributions. Methods in Ecology and Evolution. doi: 10.1111/j.2041-210X.2011.00182.x
Examples
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60 | if(requireNamespace("plotKML", quietly = TRUE) &
requireNamespace("maxlike", quietly = TRUE) &
requireNamespace("spatstat", quietly = TRUE) ){
library(plotKML)
library(maxlike)
library(spatstat)
library(maptools)
data(eberg)
data(eberg_grid)
## existing sampling plan:
sel <- runif(nrow(eberg)) < .2
eberg.xy <- eberg[sel,c("X","Y")]
coordinates(eberg.xy) <- ~X+Y
proj4string(eberg.xy) <- CRS("+init=epsg:31467")
## covariates:
gridded(eberg_grid) <- ~x+y
proj4string(eberg_grid) <- CRS("+init=epsg:31467")
## convert to continuous independent covariates:
formulaString <- ~ PRMGEO6+DEMSRT6+TWISRT6+TIRAST6
eberg_spc <- spc(eberg_grid, formulaString)
## Not run:
## derive occurrence probability:
covs <- eberg_spc@predicted[1:8]
iprob <- spsample.prob(eberg.xy, covs)
## Note: obvious omission areas:
hist(iprob[[1]]@data[,1], col="gray")
## compare with random sampling:
rnd <- spsample(eberg_grid, type="random",
n=length(iprob[["observations"]]))
iprob2 <- spsample.prob(rnd, covs)
## compare the two next to each other:
op <- par(mfrow=c(1,2))
plot(raster(iprob[[1]]), zlim=c(0,1), col=SAGA_pal[[1]])
points(iprob[["observations"]])
plot(raster(iprob2[[1]]), zlim=c(0,1), col=SAGA_pal[[1]])
points(iprob2[["observations"]])
par(op)
while (!is.null(dev.list())) dev.off()
## fit a weighted lm:
eberg.xy <- eberg[sel,c("SNDMHT_A","X","Y")]
coordinates(eberg.xy) <- ~X+Y
proj4string(eberg.xy) <- CRS("+init=epsg:31467")
eberg.xy$iprob <- over(eberg.xy, iprob[[1]])$iprob
eberg.xy@data <- cbind(eberg.xy@data, over(eberg.xy, covs))
fs <- as.formula(paste("SNDMHT_A ~ ",
paste(names(covs), collapse="+")))
## the lower the occurrence probability, the higher the weight:
w <- 1/eberg.xy$iprob
m <- lm(fs, eberg.xy, weights=w)
summary(m)
## compare to standard lm:
m0 <- lm(fs, eberg.xy)
summary(m)$adj.r.squared
summary(m0)$adj.r.squared
## End(Not run)
}
|
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