\name{RPpoisson}
\alias{RPpoisson}
\title{Simulation of Random Fields}
\description{
Shot noise model, which is also called moving
average model, trigger process, dilution random field, and by several
other names.
}
\usage{
RPpoisson(phi, intensity)
}
\arguments{
\item{phi}{the model, \command{\link{RMmodel}}, gives the shape
function to be used}
\item{intensity}{the intensity of the underlying stationary Poisson
point process
}
}
%\details{ }
\author{Martin Schlather, \email{schlather@math.uni-mannheim.de}
\url{http://ms.math.uni-mannheim.de/de/publications/software}
}
\examples{
RFoptions(seed=0) ## *ANY* simulation will have the random seed 0; set
## RFoptions(seed=NA) to make them all random again
\dontshow{StartExample()}
# example 1: Posson field based on disks with radius 1
x <- seq(0,25, 0.02)
model <- RMball()
z <- RFsimulate(RPpoisson(model), x, intensity = 2)
plot(z)
par(mfcol=c(2,1))
plot(z@data[,1:min(length(z@data), 1000)], type="l")
hist(z@data[,1], breaks=0.5 + (-1 : max(z@data)))
# example 2: Poisson field based on the normal density function
# note that
# (i) the normal density as unbounded support that has to be truncated
# (ii) the intensity is high so that the CLT holds
x <- seq(0, 10, 0.01)
model <- RMtruncsupport(radius=5, RMgauss())
z <- RFsimulate(RPpoisson(model), x, intensity = 100)
plot(z)
\dontshow{FinalizeExample()}
}
\seealso{
\command{\link{RMmodel}}
\link{RP},
\command{\link{RPcoins}}
}
\keyword{spatial}