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Stability and convergence analysis of high-order numerical schemes with DtN-type absorbing boundary conditions for nonlocal wave equations

Jihong Wang, Jerry Zhijian Yang, Jiwei Zhang

2023IMA Journal of Numerical Analysis13 citationsDOI

Abstract

Abstract The stability and convergence analysis of high-order numerical approximations for the one- and two-dimensional nonlocal wave equations on unbounded spatial domains are considered. We first use the quadrature-based finite difference schemes to discretize the spatially nonlocal operator, and apply the explicit difference scheme to approximate the temporal derivative to achieve a fully discrete infinity system. After that, we construct the Dirichlet-to-Neumann (DtN)-type absorbing boundary conditions (ABCs), to reduce the infinite discrete system into a finite discrete system. To do so, we first adopt the idea in Du et al. (2018, Commun. Comput. Phys., 24, 1049–1072) and Du et al. (2018, SIAM J. Sci. Comp., 40, A1430–A1445) to derive the Dirichlet-to-Dirichlet (DtD)-type mappings for one- and two-dimensional cases, respectively. We then use the discrete nonlocal Green’s first identity to achieve the discrete DtN-type mappings from the DtD-type mappings. The resulting DtN-type mappings make it possible to perform the stability and convergence analysis of the reduced problem. Numerical experiments are provided to demonstrate the accuracy and effectiveness of the proposed approach.

Topics & Concepts

MathematicsDiscretizationType (biology)Dirichlet distributionConvergence (economics)Stability (learning theory)Numerical analysisMathematical analysisDirichlet boundary conditionQuadrature (astronomy)Boundary value problemBoundary (topology)Applied mathematicsComputer scienceEconomic growthMachine learningEcologyEconomicsEngineeringBiologyElectrical engineeringNumerical methods in engineeringElectromagnetic Simulation and Numerical MethodsDifferential Equations and Numerical Methods