Generalization of Lax Equivalence Theorem on Unbounded Self-adjoint Operators with Applications to Schr\"odinger Operators

Abstract

Define A a unbounded self-adjoint operator on Hilbert space X . Let \ An \ be its resolvent approximation sequence with closed range R(An) (n ∈ N) , that is, An (n ∈ N) are all self-adjoint on Hilbert space X and equation* -2mm s- n ∞ Rλ (An) = Rλ (A) (λ ∈ C R), \ where \ R λ(A) := (λ I-A)-1. equation* The Moore-Penrose inverse An ∈ B(X) is a natural approximation to the Moore-Penrose inverse A . This paper shows that: A is continuous and strongly converged by \ An \ if and only if n An < +∞ . On the other hand, this result tells that arbitrary bounded computational scheme \ An \ induced by resolvent approximation \ An \ is naturally instable (that is, n An = ∞ ) for any self-adjoint operator equation with non-closed range, for example, free Schr\"odinger operator, Schr\"odinger operator with Coulumb potential and Schr\"odinger operator in model of many particles. This implies the infeasibility to globally and approximately solve non-closed range self-ajoint operator equation by resolvent approximation.