Primal finite element scheme of the Hodge-Laplace problem

Abstract

In this paper, we construct nonconforming finite element spaces VdδhΛk for the approximation of HΛk H*0Λk on simplicial meshes, for n 2 and 1 k n-1, by enforcing adjoint continuity against piecewise Whitney spaces rather than trace matching. It holds, with dkh and δk,h denoting respectively the piecewise action of differential and codifferential operators, and HhΛk being the discrete harmonic forms in the FEEC sense, that HhΛk=\μh∈ VdδhΛk:dkhμh=0,\ δk,hμh=0\, which mirrors the continuous Hodge--Laplace kernel on domains with nontrivial topology. The space is not a classical Ciarlet-type finite element space; though, a uniform discrete Poincare inequality and locally supported basis functions (supported on at most two cells) are guaranteed. The resulting primal scheme yields an O(h) error bound for smooth data and O(hs) on s-regular domains (0<s 1), nontrivial topology admitted. Two- and three-dimensional eigenvalue tests agree with the mixed method on perforated domains, which are given to verify the validity of the scheme.