Necessary and sufficient conditions for asymptotically optimal linear prediction of random fields on compact metric spaces

Abstract

Optimal linear prediction (aka. kriging) of a random field \Z(x)\x∈X indexed by a compact metric space (X,dX) can be obtained if the mean value function m and the covariance function ×X of Z are known. We consider the problem of predicting the value of Z(x*) at some location x*∈X based on observations at locations \xj\j=1n which accumulate at x* as n∞ (or, more generally, predicting (Z) based on \j(Z)\j=1n for linear functionals ,1,…,n). Our main result characterizes the asymptotic performance of linear predictors (as n increases) based on an incorrect second order structure (m,), without any restrictive assumptions on , such as stationarity. We, for the first time, provide necessary and sufficient conditions on (m,) for asymptotic optimality of the corresponding linear predictor holding uniformly with respect to . These general results are illustrated by weakly stationary random fields on X⊂Rd with Mat\'ern or periodic covariance functions, and on the sphere X=S2 for the case of two isotropic covariance functions.