Spectral approximation of elliptic operators by the Hybrid High-Order method

Abstract

We study the approximation of the spectrum of a second-order elliptic differential operator by the Hybrid High-Order (HHO) method. The HHO method is formulated using cell and face unknowns which are polynomials of some degree k≥0. The key idea for the discrete eigenvalue problem is to introduce a discrete operator where the face unknowns have been eliminated. Using the abstract theory of spectral approximation of compact operators in Hilbert spaces, we prove that the eigenvalues converge as h2t and the eigenfunctions as ht in the H1-seminorm, where h is the mesh-size, t∈ [s,k+1] depends on the smoothness of the eigenfunctions, and s>12 results from the elliptic regularity theory. The convergence rates for smooth eigenfunctions are thus h2k+2 for the eigenvalues and hk+1 for the eigenfunctions. Our theoretical findings, which improve recent error estimates for Hybridizable Discontinuous Galerkin (HDG) methods, are verified on various numerical examples including smooth and non-smooth eigenfunctions. Moreover, we observe numerically in one dimension for smooth eigenfunctions that the eigenvalues superconverge as h2k+4 for a specific value of the stabilization parameter.