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A Finite Difference Method for Two-Phase Parabolic Obstacle-like Problem

Numerical Analysis 2015-05-12 v5

Abstract

In this paper we treat the numerical approximation of the two-phase parabolic obstacle-like problem: Δuut=λ+χ{u>0}λχ{u<0},(t,x)(0,T)×Ω,\Delta u -u_t=\lambda^+\cdot\chi_{\{u>0\}}-\lambda^-\cdot\chi_{\{u<0\}},\quad (t,x)\in (0,T)\times\Omega, where T<,λ+,λ>0T < \infty, \lambda^+ ,\lambda^- > 0 are Lipschitz continuous functions, and ΩRn\Omega\subset\mathbb{R}^n is a bounded domain. We introduce a certain variational form, which allows us to define a notion of viscosity solution. We use defined viscosity solutions framework to apply Barles-Souganidis theory. The numerical projected Gauss-Seidel method is constructed. Although the paper is devoted to the parabolic version of the two-phase obstacle-like problem, we prove convergence of the discretized scheme to the unique viscosity solution for both two-phase parabolic obstacle-like and standard two-phase membrane problem. Numerical simulations are also presented.

Keywords

Cite

@article{arxiv.1111.6287,
  title  = {A Finite Difference Method for Two-Phase Parabolic Obstacle-like Problem},
  author = {Avetik Arakelyan},
  journal= {arXiv preprint arXiv:1111.6287},
  year   = {2015}
}

Comments

Numerical Analysis, Finite difference, Free boundary, Two-phase obstacle

R2 v1 2026-06-21T19:42:10.840Z