Inverse obstacle scattering for elastic waves in the time domain

TL;DR

This paper develops a novel method for solving the inverse elastic scattering problem in the time domain, using boundary integral equations and convolution quadrature, with demonstrated numerical effectiveness.

Contribution

It introduces a new convolution quadrature based nonlinear integral equation approach for inverse elastic scattering in the time domain, including proof of uniqueness.

Findings

Method effectively reconstructs obstacles from scattered field data.

Numerical experiments confirm the feasibility and accuracy of the approach.

Abstract

This paper concerns an inverse elastic scattering problem which is to determine a rigid obstacle from time domain scattered field data for a single incident plane wave. By using Helmholtz decomposition, we reduce the initial-boundary value problem of the time domain Navier equation to a coupled initial-boundary value problem of wave equations, and prove the uniqueness of the solution for the coupled problem by employing energy method. The retarded single layer potential is introduced to establish the coupled boundary integral equations, and the uniqueness is discussed for the solution of the coupled boundary integral equations. Based on the convolution quadrature method for time discretization, the coupled boundary integral equations are reformulated into a system of boundary integral equations in s-domain, and then a convolution quadrature based nonlinear integral equation method is proposed for the inverse problem. Numerical experiments are presented to show the feasibility and effectiveness of the proposed method.