Abstract
AbstractIn this article, a fully aggregation‐based algebraic multigrid strategy is developed for nonlinear contact problems of saddle point type using a mortar finite element approach. While the idea of extending multigrid methods to saddle point systems can already be found, for example, in the context of Stokes and Oseen equations in literature, the main contributions of this work are (i) the development and open‐source implementation of an interface aggregation strategy specifically suited for generating Lagrange multiplier aggregates that are required for coupling structural equilibrium equations with contact constraints and (ii) a review of saddle point smoothers in the context of constrained interface problems. The new interface aggregation strategy perfectly fits into an aggregation‐based multigrid framework and can easily be combined with segregated transfer operators, which allow to preserve the saddle point structure on the coarse levels. Further analysis provides insight into saddle point smoothers applied to contact problems, while numerical experiments illustrate the robustness of the new method. We have implemented the proposed algorithm within the MueLu package of the open‐source Trilinos project. Numerical examples demonstrate the robustness of the proposed method in complex dynamic contact problems as well as its scalability up to 23.9 million unknowns on 480 MPI ranks.
Highlights
Many engineering applications require the simulation of large-scale contact problems
We address the case of mortar-based contact problems in saddle point formulation and show how to tailor iterative solvers with algebraic multigrid preconditioners to such problems
Inspired by our prior work on fluid-structure interaction [27, 47], where we have investigated the beneficial effect of satisfying interface constraints within the preconditioner, we will use segregated transfer operators suitable for block matrices to transfer and incorporate the contact constraints in all coarse levels
Summary
Many engineering applications require the simulation of large-scale contact problems. It is not surprising that recent years have seen significant progress in modelling and simulation of contact interaction and its associated phenomena, such as friction [28, 52, 66], wear [16, 24, 44, 48], adhesion [45, 65], or multi-scale contact phenomena [10, 73] This is true with regard to robust finite element based discretization techniques for finite deformations and efficient nonlinear solution algorithms.
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