Reproducing Kernels of Generalized Sobolev Spaces via a Green Function Approach with Differential Operators

Abstract

In this paper we introduce a generalization of the classical 2()-based Sobolev spaces with the help of a vector differential operator P which consists of finitely or countably many differential operators Pn which themselves are linear combinations of distributional derivatives. We find that certain proper full-space Green functions G with respect to L=P TP are positive definite functions. Here we ensure that the vector distributional adjoint operator P of P is well-defined in the distributional sense. We then provide sufficient conditions under which our generalized Sobolev space will become a reproducing-kernel Hilbert space whose reproducing kernel can be computed via the associated Green function G. As an application of this theoretical framework we use G to construct multivariate minimum-norm interpolants sf,X to data sampled from a generalized Sobolev function f on X. Among other examples we show the reproducing-kernel Hilbert space of the Gaussian function is equivalent to a generalized Sobolev space.