https://github.com/cran/RandomFields
Tip revision: 0e562f038613e9388e8c33a6cf59f7f57ae62bf5 authored by Martin Schlather on 03 August 2014, 00:00:00 UTC
version 3.0.32
version 3.0.32
Tip revision: 0e562f0
RMnsst.Rd
\name{RMnsst}
\alias{RMnsst}
\title{Non-Separable Space-Time model}
\description{
\command{\link{RMnsst}} is a univariate stationary spaceisotropic covariance model
whose corresponding covariance is given by
\deqn{C(h,u)= (\psi(u)+1)^{-\delta/2} \phi(h /\sqrt(\psi(u) +1))}
}
\usage{
RMnsst(phi, psi, delta, var, scale, Aniso, proj)
}
\arguments{
\item{phi}{is normal mixture \command{\link{RMmodel}}.}
\item{psi}{is a variogram \command{\link{RMmodel}}.}
\item{delta}{a numerical value; must be greater than or equal to the spatial dimension of the field}
\item{var,scale,Aniso,proj}{optional arguments; same meaning for any
\command{\link{RMmodel}}. If not passed, the above
covariance function remains unmodified.}
}
\details{
This model is used for space-time modelling where the spatial
component is isotropic.
}
\value{
\command{\link{RMnsst}} returns an object of class \code{\link[=RMmodel-class]{RMmodel}}.
}
\references{
\itemize{
\item Gneiting, T. (1997) Normal scale mixtures and dual probability
densitites, \emph{J. Stat. Comput. Simul.} \bold{59}, 375-384.
\item Gneiting, T. (2002) Nonseparable, stationary covariance
functions for space-time data, \emph{JASA} \bold{97}, 590-600.
\item Gneiting, T. and Schlather, M. (2001)
Space-time covariance models.
In El-Shaarawi, A.H. and Piegorsch, W.W.:
\emph{The Encyclopedia of Environmetrics.} Chichester: Wiley.
% \item Zastavnyi, V. and Porcu, E. (2011)
% Caracterization theorems for the Gneiting class space-time
% covariances.
% \emph{Bernoulli}, \bold{??}.
\item Schlather, M. (2010)
On some covariance models based on normal scale mixtures.
\emph{Bernoulli}, \bold{16}, 780-797.
}
}
\author{Martin Schlather, \email{schlather@math.uni-mannheim.de}
}
\seealso{
\command{\link{RMmodel}},
\command{\link{RFsimulate}},
\command{\link{RFfit}}.
}
\keyword{spatial}
\keyword{models}
\examples{
RFoptions(seed=0) ## *ANY* simulation will have the random seed 0; set
## RFoptions(seed=NA) to make them all random again
model <- RMnsst(phi=RMgauss(), psi=RMfbm(alpha=1), delta=2)
x <- seq(0, 10, if (interactive()) 0.2 else 1)
plot(model, ylim=c(-1,1), dim=2)
plot(RFsimulate(model, x=x, y=x))
\dontshow{FinalizeExample()}
}