English

A Nitsche-type Method for Helmholtz Equation with an Embedded Acoustically Permeable Interface

Numerical Analysis 2016-03-01 v2

Abstract

We propose a new finite element method for Helmholtz equation in the situation where an acoustically permeable interface is embedded in the computational domain. A variant of Nitsche's method, different from the standard one, weakly enforces the impedance conditions for transmission through the interface. As opposed to a standard finite-element discretization of the problem, our method seamlessly handles a complex-valued impedance function ZZ that is allowed to vanish. In the case of a vanishing impedance, the proposed method reduces to the classic Nitsche method to weakly enforce continuity over the interface. We show stability of the method, in terms of a discrete G{\aa}rding inequality, for a quite general class of surface impedance functions, provided that possible surface waves are sufficiently resolved by the mesh. Moreover, we prove an a priori error estimate under the assumption that the absolute value of the impedance is bounded away from zero almost everywhere. Numerical experiments illustrate the performance of the method for a number of test cases in 2D and 3D with different interface conditions.

Keywords

Cite

@article{arxiv.1511.09363,
  title  = {A Nitsche-type Method for Helmholtz Equation with an Embedded Acoustically Permeable Interface},
  author = {Esubalewe Lakie Yedeg and Eddie Wadbro and Peter Hansbo and Mats G. Larson and Martin Berggren},
  journal= {arXiv preprint arXiv:1511.09363},
  year   = {2016}
}
R2 v1 2026-06-22T11:57:37.112Z