A generalization of pde's from a Krylov point of view

Abstract

We introduce and investigate the notion of a `generalized equation' of the form f(D2 u)=0, based on the notions of subequations and Dirichlet duality. Precisely, a subset H⊂ Sym2( Rn) is a generalized equation if it is an intersection H = E (- G) where E and G are subequations and G is the subequation dual to G. We utilize a viscosity definition of `solution' to H. The mirror of H is defined by H* G (- E). One of the main results here concerns the Dirichlet problem on arbitrary bounded domains ⊂ Rn for solutions to H with prescribed boundary function ∈ C(∂ ). We prove that: (A) Uniqueness holds H has no interior, and (B) Existence holds H* has no interior. For (B) the appropriate boundary convexity of ∂ must be assumed. Many examples of generalized equations are discussed, including the constrained Laplacian, the twisted Monge-Amp\`ere equation, and the C1,1-equation. The closed sets H which can be written as generalized equations are intrinsically characterized. For such an H the set of subequation pairs with H = E (- G) is partially ordered, and there is a canonical least element, contained in all others. Harmonics for the canonical equation are harmonic for all others giving H. A general form of the main theorem, which holds on any manifold, is also established.