Acoustic waves in a medium bounded by curved surfaces

Abstract

A method for obtaining quasi-analytic solutions to the three-dimensional (3D) Helmholtz equation for the case of an acoustic medium bounded by two identical curved surfaces is presented. The method can be extended to a semi-infinite medium with a curved boundary for the study of Rayleigh waves on a non-planar surface, albeit the solution procedure entails the numerical matrix method. The formulation of the method is based on the differential-geometry argument employing the curved coordinates ( u 1 , u 2 , u 3 ) where u 1 and u 2 are along the local tangent plane of one of the bounding surfaces z = z ( x ) and u 3 is perpendicular to the local tangent plane. This choice of coordinates allows the 3D Helmholtz equation, subject to boundary conditions specified on non-planar surfaces, to be solved with relative ease. Normal-mode solutions are shown for the case of a fluid layer with two pressure-release boundaries, where the bounding surfaces are given by the ramp, the Gaussian, and the sinusoidal functions, respectively.