On Temple--Kato like inequalities and applications

TL;DR

This paper develops new eigenvalue bounds for unbounded positive operators in Hilbert spaces, extending Temple--Kato inequalities with applications to Schrödinger operators and finite element methods.

Contribution

It introduces a quadratic form-based approach to eigenvalue estimates, applicable to unbounded operators and perturbations, using simple matrix tools.

Findings

Derived scaling robust eigenvalue estimates

Applied results to Schrödinger operators

Provided convergence estimates for finite element approximations

Abstract

We give both lower and upper estimates for eigenvalues of unbounded positive definite operators in an arbitrary Hilbert space. We show scaling robust relative eigenvalue estimates for these operators in analogy to such estimates of current interest in Numerical Linear Algebra. Only simple matrix theoretic tools like Schur complements have been used. As prototypes for the strength of our method we discuss a singularly perturbed Schroedinger operator and study convergence estimates for finite element approximations. The estimates can be viewed as a natural quadratic form version of the celebrated Temple--Kato inequality.