English

A quasi-interpolation operator yielding fully computable error bounds

Numerical Analysis 2025-07-17 v1 Numerical Analysis

Abstract

We design a quasi-interpolation operator from the Sobolev space H01(Ω)H^1_0(\Omega) to its finite-dimensional finite element subspace formed by piecewise polynomials on a simplicial mesh with a computable approximation constant. The operator 1) is defined on the entire H01(Ω)H^1_0(\Omega), no additional regularity is needed; 2) allows for an arbitrary polynomial degree; 3) works in any space dimension; 4) is defined locally, in vertex patches of mesh elements; 5) yields optimal estimates for both the H1H^1 seminorm and the L2L^2 norm error; 6) gives a computable constant for both the H1H^1 seminorm and the L2L^2 norm error; 7) leads to the equivalence of global-best and local-best errors; 8) possesses the projection property. Its construction follows the so-called potential reconstruction from a posteriori error analysis. Numerical experiments illustrate that our quasi-interpolation operator systematically gives the correct convergence rates in both the H1H^1 seminorm and the L2L^2 norm and its certified overestimation factor is rather sharp and stable in all tested situations.

Keywords

Cite

@article{arxiv.2507.11819,
  title  = {A quasi-interpolation operator yielding fully computable error bounds},
  author = {T. Chaumont-Frelet and M. Vohralik},
  journal= {arXiv preprint arXiv:2507.11819},
  year   = {2025}
}
R2 v1 2026-07-01T04:03:25.781Z