Hybrid high-order (HHO) methods for elliptic diffusion problems have been originally formulated for loads in the Lebesgue space L 2 (Ω). In this paper we devise and analyse a variant thereof, which is defined for any load in the dual Sobolev space H −1 (Ω). The main feature of the present variant is that its H 1 -norm error can be bounded only in terms of the H 1 -norm best error in a space of broken polynomials. We establish this estimate with the help of recent results on the quasi-optimality of nonconforming methods. We prove also an improved error bound in the L 2 -norm by duality. Compared to previous works on quasi-optimal nonconforming methods the main novelties are that HHO methods handle pairs of unknowns and not a single function and, more crucially, that these methods employ a reconstruction that is one polynomial degree higher than the discrete unknowns. The proposed modification affects only the formulation of the discrete right-hand side. This is obtained by properly mapping discrete test functions into H 1 0 (Ω).
A quasi-optimal variant of the hybrid high-order method for elliptic partial differential equations with H−1 loads / A. Ern, P. Zanotti. - In: IMA JOURNAL OF NUMERICAL ANALYSIS. - ISSN 0272-4979. - 40:4(2020 Oct), pp. 2163-2188.
A quasi-optimal variant of the hybrid high-order method for elliptic partial differential equations with H−1 loads
P. Zanotti
2020
Abstract
Hybrid high-order (HHO) methods for elliptic diffusion problems have been originally formulated for loads in the Lebesgue space L 2 (Ω). In this paper we devise and analyse a variant thereof, which is defined for any load in the dual Sobolev space H −1 (Ω). The main feature of the present variant is that its H 1 -norm error can be bounded only in terms of the H 1 -norm best error in a space of broken polynomials. We establish this estimate with the help of recent results on the quasi-optimality of nonconforming methods. We prove also an improved error bound in the L 2 -norm by duality. Compared to previous works on quasi-optimal nonconforming methods the main novelties are that HHO methods handle pairs of unknowns and not a single function and, more crucially, that these methods employ a reconstruction that is one polynomial degree higher than the discrete unknowns. The proposed modification affects only the formulation of the discrete right-hand side. This is obtained by properly mapping discrete test functions into H 1 0 (Ω).Pubblicazioni consigliate
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