Characterization of the second order random fields subject to linear distributional PDE constraints

Abstract

Let L be a linear differential operator acting on functions defined over an open set D⊂ Rd. In this article, we characterize the measurable second order random fields U = (U(x))x∈D whose sample paths all verify the partial differential equation (PDE) L(u) = 0, solely in terms of their first two moments. When compared to previous similar results, the novelty lies in that the equality L(u) = 0 is understood in the sense of distributions, which is a powerful functional analysis framework mostly designed to study linear PDEs. This framework enables to reduce to the minimum the required differentiability assumptions over the first two moments of (U(x))x∈D as well as over its sample paths in order to make sense of the PDE L(Uω)=0. In view of Gaussian process regression (GPR) applications, we show that when (U(x))x∈D is a Gaussian process (GP), the sample paths of (U(x))x∈D conditioned on pointwise observations still verify the constraint L(u)=0 in the distributional sense. We finish by deriving a simple but instructive example, a GP model for the 3D linear wave equation, for which our theorem is applicable and where the previous results from the literature do not apply in general.