Variational p-harmonious functions: existence and convergence to p-harmonic functions
Abstract
In a recent paper, the last three authors showed that a game-theoretic p-harmonic function v is characterized by an asymptotic mean value property with respect to a kind of mean value pr[v](x) defined variationally on balls Br(x). In this paper, in a domain ⊂N, N 2, we consider the operator μp, acting on continuous functions on , defined by the formula μp[v](x)=r(x)p[v](x), where r(x)=[,(x,)] and denotes the boundary of . We first derive various properties of μp such as continuity and monotonicity. Then, we prove the existence and uniqueness of a function u∈ C() satisfying the Dirichlet-type problem: u(x)=μp[u](x) \ for every \ x∈, u=g \ on \ , for any given function g∈ C(). This result holds, if we assume the existence of a suitable notion of barrier for all points in . That u is what we call the variational p-harmonious function with Dirichlet boundary data g, and is obtained by means of a Perron-type method based on a comparison principle. We then show that the family \ u\>0 gives an approximation scheme for the viscosity solution u∈ C() of pG u=0 \ in , u=g \ on \ , where pG is the so-called game-theoretic (or homogeneous) p-Laplace operator. In fact, we prove that u converges to u, uniformly on as 0.
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