A new approach to the optimal modeling of sound propagation in the random ocean

Abstract

Consideration is given to an optimal modeling problem for the general horizontally stratified ocean, which is assumed to be a random inhomogeneous medium. The random acoustic wave velocity potential p=p(x, y, z) in the ocean is described by the stochastic Helmholtz equation Delta p+k/sup 2/p=0, where Delta is the standard Laplacian partial differential operator, and k=k(x, y, z) is the random wave number. Because of the random and inhomogeneous nature of the ocean, not only the amplitude and phase fluctuations of the sound wave but also its scattering have to be taken into account in the mathematical modeling of the random wave propagation. In this consideration, p is decomposed as p=p/sub 0/+p/sub s/, where p/sub 0/ is the deterministic component (the unperturbed part) of the velocity potential (which can be determined by some existing techniques) and p/sub s/ is the random component created essentially by a perturbation. A novel method for obtaining an optimal estimate of p/sub s/ is proposed. It is based on a PDL/sub g/-spline theory and technique developed by the authors, so that p can be determined optimally and efficiently for the purpose of applications. >