Approximation of harmonic functions on metric measure spaces of controlled geometry via discrete graphs

Abstract

Given a complete doubling metric measure space X that supports a 2-Poincar\'e inequality, we approximate harmonic functions on a bounded domain with a prescribed Newton-Sobolev boundary data. Our approach is based on the approximation of the underlying space X by a family of graphs. This approximated harmonic function is realized as the weak limit of a sequence of functions obtained from the graph minimizers. We prove that such a function is a minimizer with respect to a nonlinear energy form on N1,20(), which is in turn, majorized by the upper gradient energy on N1,2(X). This energy form on N1,20() is obtained as a -limit of a sequence of induced energy forms projected from the discrete energy form on the approximating graphs.