We consider wave propagation in a coupled fluid-solid region separated by a static but possibly curved interface. The wave propagation is modeled by the acoustic wave equation in terms of a velocity potential in the fluid, and the elastic wave equation for the displacement in the solid. At the fluid solid interface, we impose suitable interface conditions to couple the two equations. We use a recently developed energy-based discontinuous Galerkin method to discretize the governing equations in space. Both energy conserving and upwind numerical fluxes are derived to impose the interface conditions. The highlights of the developed scheme include provable energy stability and high order accuracy. We present numerical experiments to illustrate the accuracy property and robustness of the developed scheme.

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Volume119, Issue7

17 August 2019

Pages 618-638

An energy-based discontinuous Galerkin method for coupled elasto-acoustic wave equations in second-order form

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An energy-based discontinuous Galerkin method for coupled elasto-acoustic wave equations in second-order form

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