Boundary quasi-orthogonality and sharp inclusion bounds for large Dirichlet eigenvalues

Abstract

We study eigenfunctions and eigenvalues of the Dirichlet Laplacian on a bounded domain Ω⊂n with piecewise smooth boundary. We bound the distance between an arbitrary parameter E > 0 and the spectrum \Ej \ in terms of the boundary L2-norm of a normalized trial solution u of the Helmholtz equation (Δ+ E)u = 0. We also bound the L2-norm of the error of this trial solution from an eigenfunction. Both of these results are sharp up to constants, hold for all E greater than a small constant, and improve upon the best-known bounds of Moler--Payne by a factor of the wavenumber E. One application is to the solution of eigenvalue problems at high frequency, via, for example, the method of particular solutions. In the case of planar, strictly star-shaped domains we give an inclusion bound where the constant is also sharp. We give explicit constants in the theorems, and show a numerical example where an eigenvalue around the 2500th is computed to 14 digits of relative accuracy. The proof makes use of a new quasi-orthogonality property of the boundary normal derivatives of the eigenmodes, of interest in its own right.