Quantitative Ray Methods for Scattering of Sound by Spherical Shells

Abstract

The application of ray methods to the scattering of high-frequency plane waves from evacuated elastic spherical shells is investigated. The investigation of ray methods for spherical shells is a precursor to the application of such methods to shells having more complicated shapes. Ray models are developed to synthesize the form function f(Theta, ka) where k is the wavenumber of the incident wave and Theta is the scattering angle. The forward scattering amplitude, f(Theta = 0), is related to the extinction cross section, sigma sub e by the optical theorem. If the absorption by the scatterer is negligible, the sigma sub e is equal to the total scattering cross section sigma sub t. A ray synthesis partition f(Theta = 0) into a component for ordinary forward diffraction about the shell, f sub FD, and contributions from surface guided elastic waves. For high-frequency scattering, the relevant surface guided elastic waves are leaky Lamb waves. A similar ray synthesis of the backscattering amplitude f(Theta = pi) contains a specular reflection component, f sub sp(Theta = pi), and leaky Lamb wave contributions. A generalization of the geometrical theory of diffraction is employed to synthesize f sub l(Theta = 0, ka) and f sub l (Theta = pi, ka) for the lth leaky Lamb wave contribution. The syntheses for forward and backwards scattering correctly describe the leaky Lamb wave contributions and are expressible in a Fabry-Perot resonator form. While the ray description of backscattering ordinarily accurately reproduces exact computations and experiments with tone burst, certain anomalies are discussed.

Document Details

Document Type

Technical Report

Publication Date

Aug 01, 1991

Accession Number

ADA240255

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