What does this research mean for the field?

A reliable a posteriori error estimator for elastoplasticity problems with linearly kinematic hardening is derived, demonstrating local efficiency estimates. Novelty: ClaimNovelty.METHODOLOGICAL. Consensus alignment: ConsensusAlignment.NEUTRAL.

What question did this study set out to answer?

The aim is to develop a reliable a posteriori error estimator for elastoplasticity problems.

February 26, 2026Open Access

A posteriori error estimates for hp-FE discretizations in elastoplasticity

Key Points

The aim is to develop a reliable a posteriori error estimator for elastoplasticity problems.
Derived error estimator for elastoplasticity with kinematic hardening.
Examined hp-finite element discretizations using different variational formulations.
Conducted numerical experiments to test theoretical findings.
The error estimator provided local efficiency estimates.
Adaptive hp-finite element methods improved accuracy for elastoplasticity problems.
Numerical examples confirmed the applicability of the proposed methods.

Abstract

In this paper, a reliable a posteriori error estimator for a model problem of elastoplasticity with linearly kinematic hardening is derived, which satisfies some (local) efficiency estimates. It is applicable to any discretization that is conforming with respect to the displacement field and the plastic strain. Furthermore, the paper presents hp-finite element discretizations relying on a variational inequality as well as on a mixed variational formulation and discusses their equivalence by using biorthogonal basis functions. Numerical experiments demonstrate the applicability of the theoretical findings and underline the potential of h- and hp-adaptive finite element discretizations for problems of elastoplasticity.

A posteriori error estimates for hp-FE discretizations in elastoplasticity

Key Points

Abstract

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