Generalization of Lax Equivalence Theorem on Unbounded Self-adjoint Operators with Applications to Schrödinger Operators (1708.04456v9)
Abstract: Define $ A $ a unbounded self-adjoint operator on Hilbert space $ X $. Let $ { A_n } $ be its resolvent approximation sequence with closed range $ \mathcal{R}(A_n) (n \in \mathrm{N}) $, that is, $ A_n (n \in \mathrm{N}) $ are all self-adjoint on Hilbert space $ X $ and \begin{equation*} \hbox{ \raise-2mm\hbox{$\textstyle s-\lim \atop \scriptstyle {n \to \infty}$}} R_\lambda (A_n) = R_\lambda (A)\quad (\lambda \in \mathrm{C} \setminus \mathrm{R}), \ \textrm{where} \ R_ \lambda(A) := (\lambda I-A){-1}. \end{equation*} The Moore-Penrose inverse $ A\dagger_n \in \mathcal{B}(X) $ is a natural approximation to the Moore-Penrose inverse $ A\dagger $. This paper shows that: $ A\dagger $ is continuous and strongly converged by $ { A\dagger_n } $ if and only if $ \sup\limits_n \Vert A\dagger_n \Vert < +\infty $. On the other hand, this result tells that arbitrary bounded computational scheme $ { A\dagger_n } $ induced by resolvent approximation $ { A_n } $ is naturally instable (that is, $ \sup_n \Vert A\dagger_n \Vert = \infty $) for any self-adjoint operator equation with non-closed range, for example, free Schr\"{o}dinger operator, Schr\"{o}dinger operator with Coulumb potential and Schr\"{o}dinger 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.
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