\name{Tail Correlation Functions} \alias{tcf} \alias{tail correlation functions} \alias{Tail correlation functions} \alias{RMmodelsTailCorrelation} \title{Covariance models valid for max-stable random fields} \description{ This page summarizes the models that can be used for tail correlation functions. } \details{ The following models are available: \bold{Completely monotone functions allowing for arbitrary scale} \tabular{ll}{ \command{\link{RMbcw}} \tab Model bridging stationary and intrinsically stationary processes for \code{alpha <= 1} and \code{beta < 0}\cr \command{\link{RMdagum}} \tab Dagum model with \eqn{\beta < \gamma} and \eqn{\gamma \le 1}\cr \command{\link{RMexp}} \tab exponential model \cr \command{\link{RMgencauchy}} \tab generalized Cauchy family with \eqn{\alpha \le 1} (and arbitrary \eqn{\beta> 0})\cr \command{\link{RMmatern}} \tab Whittle-Matern model with \eqn{\nu \le 1/2}\cr %multiquadric todo %sine power todo \command{\link{RMstable}} \tab symmetric stable family or powered exponential model with \eqn{\alpha \le 1}\cr \command{\link{RMwhittle}} \tab Whittle-Matern model, alternative parametrization with \eqn{\nu \le 1/2}\cr } \bold{Other isotropic models with arbitrary scale} \tabular{ll}{ \command{\link{RMnugget}} \tab nugget effect model \cr } \bold{Compactly supported covariance functions} \tabular{ll}{ \command{\link{RMaskey}} \tab Askey's model\cr \command{\link{RMcircular}} \tab circular model\cr \command{\link{RMconstant}}\tab identically constant \cr \command{\link{RMcubic}} \tab cubic model\cr \command{\link{RMgengneiting}} \tab Wendland-Gneiting model; differentiable models with compact support \cr \command{\link{RMgneiting}} \tab differentiable model with compact support \cr \command{\link{RMspheric}} \tab spherical model \cr } \bold{Anisotropic models} \tabular{ll}{ None up to now. } \bold{Basic Operators} \tabular{ll}{ \command{\link{RMmult}}, \code{*} \tab product of covariance models \cr \command{\link{RMplus}}, \code{+} \tab sum of covariance models or variograms\cr } \bold{Operators related to process constructions} \tabular{ll}{ \command{\link{RMbernoulli}} \tab correlation of binary fields\cr \command{\link{RMbrownresnick}}\tab tcf of a \link{Brown-Resnick} process\cr \command{\link{RMschlather}}\tab tcf of an extremal Gaussian process / \link[=RMschlather]{Schlather} process \cr \command{\link{RMm2r}}\tab M2 process with monotone shape function\cr \command{\link{RMm3b}}\tab M3 process with balls of random radius\cr \command{\link{RMmps}}\tab M3 process with hyperplane polygons\cr % \command{\link{}}\tab \cr } \bold{See \link{RMmodels} for cartesian models.} } \references{ \itemize{ \item Strokorb, K., Ballani, F., and Schlather, M. (2015) Tail correlation functions of max-stable processes: Construction principles, recovery and diversity of some mixing max-stable processes with identical TCF. \emph{Extremes}, \bold{18}, 241-271 } } \me \seealso{ \link{coordinate systems}, \link{RM}, \command{\link{RMmodels}}, \command{\link{RMtrafo}}. } \keyword{spatial} \keyword{models} \examples{\dontshow{StartExample()} RFoptions(seed=0) ## *ANY* simulation will have the random seed 0; set ## RFoptions(seed=NA) to make them all random again RFgetModelNames(type="tail") ## an example of a simple model model <- RMexp(var=1.6, scale=0.5) + RMnugget(var=0) #exponential + nugget plot(model) \dontshow{FinalizeExample()}}