$H^1$-Stability of the $L^2$-Projection onto Finite Element Spaces on Adaptively Refined Quadrilateral Meshes

TL;DR

This paper investigates conditions under which the $L^2$-projection onto finite element spaces remains stable in the $H^1$ norm on adaptively refined quadrilateral meshes, demonstrating stability for certain refinement strategies and polynomial degrees.

Contribution

It provides local criteria for $H^1$-stability of $L^2$-projections on adaptively refined quadrilateral meshes and proves stability for specific refinement strategies and polynomial degrees.

Findings

Adaptive refinement strategies are $H^1$-stable for polynomial degrees 2 to 9.

Stability criteria are based on local mesh refinement properties.

Results apply to 2D quadrilateral meshes with specific refinement schemes.

Abstract

The $L^2$-orthogonal projection $\Pi_h:L^2(\Omega)\rightarrow\mathbb{V}_h$ onto a finite element (FE) space $\mathbb{V}_h$ is called $H^1$-stable iff $\|\nabla\Pi_h u\|_{L^2(\Omega)}\leq C\|u\|_{H^1(\Omega)}$, for any $u\in H^1(\Omega)$ with a positive constant $C\neq C(h)$ independent of the mesh size $h>0$. In this work, we discuss local criteria for the $H^1$-stability of adaptively refined meshes. We show that adaptive refinement strategies for quadrilateral meshes in 2D (Q-RG and Q-RB), introduced originally in Bank et al. 1982 and Kobbelt 1996, are $H^1$-stable for FE spaces of polynomial degree $p=2,\ldots,9$.