Develops a model-independent energy-based CutFEM formulation for finite-strain elasticity using automatic differentiation, with cut-independent stability analysis and convergence results for both smooth solutions and corner singularities.
Deriving robust unfitted finite element methods from augmented Lagrangian formulations
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abstract
In this paper we will discuss different coupling methods {suitable for use in} the framework of the recently introduced CutFEM paradigm, cf. Burman, Erik; Claus, Susanne; Hansbo, Peter; Larson, Mats G.; Massing, Andr\'e . CutFEM: discretizing geometry and partial differential equations. Internat. J. Numer. Methods Engrg. 104 (2015), no. 7, 472-501. In particular we will consider mortaring using Lagrange multipliers on the one hand and Nitsche's method on the other. For simplicity we will first discuss these method in the setting of uncut meshes, and end with some comments on the extension to CutFEM. We will, for comparison, discuss some different types of problems such as high contrast problems and problems with stiff coupling or adhesive contact. We will review some of the existing methods for these problems and propose some alternative methods resulting from crossovers from the Lagrange multiplier framework to Nitsche's method and vice versa.
fields
math.NA 1years
2026 1verdicts
UNVERDICTED 1representative citing papers
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A Unified CutFEM Formulation for Finite-Strain Elasticity: Energy Minimisation and Corner Singularities
Develops a model-independent energy-based CutFEM formulation for finite-strain elasticity using automatic differentiation, with cut-independent stability analysis and convergence results for both smooth solutions and corner singularities.