RADIAL COMPLEX SCALING FOR ANISOTROPIC SCALAR RESONANCE PROBLEMS

The complex scaling/perfectly matched layer method is a widely spread technique to simulate wave propagation problems in open domains. The method is very popular because its implementation is very easy and does not require any knowledge of a fundamental solution. However, for anisotropic media the method may yield an unphysical radiation condition and lead to erroneous and unstable results. In this article we argue that a radial scaling (opposed to a Cartesian scaling) does not suffer from this drawback and produces the desired radiation condition. This result is of great importance as it rehabilitates the application of the complex scaling method for anisotropic media. To present further details we consider the radial complex scaling method for scalar anisotropic resonance problems. We prove that the associated operator is Fredholm and show the convergence of approximations generated by simulateneous domain truncation and finite element discretization. We present computational studies to undergird our theoretical results.

Automated summary

The article discusses the importance of the radial scaling method for anisotropic media, and how it produces the desired radiation condition. It also proves that the associated operator is a Fredholm operator, and shows the convergence of approximations. Computational studies are presented to support the theoretical results.