English

Interpolation-based immersogeometric analysis methods for multi-material and multi-physics problems

Numerical Analysis 2024-02-27 v1 Numerical Analysis

Abstract

Immersed boundary methods are high-order accurate computational tools used to model geometrically complex problems in computational mechanics. While traditional finite element methods require the construction of high-quality boundary-fitted meshes, immersed boundary methods instead embed the computational domain in a background grid. Interpolation-based immersed boundary methods augment existing finite element software to non-invasively implement immersed boundary capabilities through extraction. Extraction interpolates the background basis as a linear combination of Lagrange polynomials defined on a foreground mesh, creating an interpolated basis that can be easily integrated by existing methods. This work extends the interpolation-based immersed boundary method to multi-material and multi-physics problems. Beginning from level-set descriptions of domain geometries, Heaviside enrichment is implemented to accommodate discontinuities in state variable fields across material interfaces. Adaptive refinement with truncated hierarchical B-splines is used to both improve interface geometry representations and resolve large solution gradients near interfaces. Multi-physics problems typically involve coupled fields where each field has unique discretization requirements. This work presents a novel discretization method for coupled problems through the application of extraction, using a single foreground mesh for all fields. Numerical examples illustrate optimal convergence rates for this method in both 2D and 3D, for heat conduction, linear elasticity, and a coupled thermo-mechanical problem. The utility of this method is demonstrated through image-based analysis of a composite sample, where in addition to circumventing typical meshing difficulties, this method reduces the required degrees of freedom compared to classical boundary-fitted finite element methods.

Keywords

Cite

@article{arxiv.2402.15937,
  title  = {Interpolation-based immersogeometric analysis methods for multi-material and multi-physics problems},
  author = {Jennifer E. Fromm and Nils Wunsch and Kurt Maute and John A. Evans and Jiun-Shyan Chen},
  journal= {arXiv preprint arXiv:2402.15937},
  year   = {2024}
}
R2 v1 2026-06-28T14:59:15.916Z