English

Data-driven, structure-preserving approximations to entropy-based moment closures for kinetic equations

Numerical Analysis 2021-06-17 v1 Numerical Analysis Computational Physics

Abstract

We present a data-driven approach to construct entropy-based closures for the moment system from kinetic equations. The proposed closure learns the entropy function by fitting the map between the moments and the entropy of the moment system, and thus does not depend on the space-time discretization of the moment system and specific problem configurations such as initial and boundary conditions. With convex and C2C^2 approximations, this data-driven closure inherits several structural properties from entropy-based closures, such as entropy dissipation, hyperbolicity, and H-Theorem. We construct convex approximations to the Maxwell-Boltzmann entropy using convex splines and neural networks, test them on the plane source benchmark problem for linear transport in slab geometry, and compare the results to the standard, optimization-based MN_N closures. Numerical results indicate that these data-driven closures provide accurate solutions in much less computation time than the MN_N closures.

Keywords

Cite

@article{arxiv.2106.08973,
  title  = {Data-driven, structure-preserving approximations to entropy-based moment closures for kinetic equations},
  author = {William A. Porteous and M. Paul Laiu and Cory D. Hauck},
  journal= {arXiv preprint arXiv:2106.08973},
  year   = {2021}
}
R2 v1 2026-06-24T03:16:49.910Z