Superconvergent Gradient Recovery for Virtual Element Methods
Abstract
Virtual element methods is a new promising finite element methods using general polygonal meshes. Its optimal a priori error estimates are well established in the literature. In this paper, we take a different viewpoint. We try to uncover the superconvergent property of the virtual element methods by doing some local post-processing only on the degrees of freedom. Using linear virtual element method as an example, we propose a universal recovery procedure to improve the accuracy of gradient approximation for numerical methods using general polygonal meshes. Its capability of serving as a posteriori error estimators in adaptive methods is also investigated. Compared to the existing residual-type a posteriori error estimators for the virtual element methods, the recovery-type a posteriori error estimator based on the proposed gradient recovery technique is much simpler in implementation and asymptotically exact. A series of benchmark tests are presented to numerically illustrate the superconvergence of recovered gradient and validate the asymptotical exactness of the recovery-based a posteriori error estimator.
Cite
@article{arxiv.1804.10194,
title = {Superconvergent Gradient Recovery for Virtual Element Methods},
author = {Hailong Guo and Cong Xie and Ren Zhao},
journal= {arXiv preprint arXiv:1804.10194},
year = {2019}
}
Comments
Mathematical Models and Methods in Applied Sciences, 2019