An explicit general form is derived for the depth-dependent Green’s function occurring in the integral solution to the Helmholtz wave equation for range-independent layered media. This representation permits arbitrary location of the source and receiver. In addition, a technique, the Fast Field Program (FFP), for the evaluation of the integral solution is delineated. Examples of the use of both the formulation and the FFP to the problem of modeling underwater acoustic propagation loss versus range, where the source/receiver are in air/water, in water/bottom, and in a cross-layer surface duct, are discussed.
With 21 FiguresIn this chapter an attempt is made to summarize those models of propagation loss in the field of underwater acoustics which have been converted into an automated computer code capable of being executed by someone other than the originator for a wide variety of problems. No single model currently exists which is adequate for all aoplications. This is perhaps not surprising considering the diversity of the ocean environment and its boundaries, and the concomitant fact that the acoustic frequencies of interest span the regime from less than 10 Hz to greater than 100 kHz. As a result a large number of models, each with its own domain of validity which in many cases is difficult to precisely define, have been developed. Their sheer number makes an exhaustive summary impossible within these limited pages. Thus it was decided to limit consideration to those models which purport to be a solution of the wave equation found in Sect.2.2.1. Fundamentally these models consider the ocean to be a deterministic environment for which the speed of sound is only a function of the spatial coordinates. Non-deterministic effects, if accounted for at all, are included in an ad hoc fashion following the determination of the deterministic propagation loss result. Model development work for the more general problem is required and is in progress. However, this effort has not reached the point where "hands off" computer codes are available. This is due in part to a lack of available experimental! environmental data and the need for larger and faster computers.The models to be discussed can then be further segregated into range independent and range dependent categori es. The former assume that the ocean is cyl i ndri ca lly symmetrical, the speed of sound an arbitrary function of only the depth (z) coordinate, and that all boundaries are parallel with the range (r) coordinate. These models discussed, in Sect.3.1, are in a fairly complete state of development as evidenced by the concern with reducing computer execution time and memory without significantly sacrificing accuracy. The range-dependent models, taken up in Sect.3.2, allow for the speed of sound to be an arbitrary function of either 2 or 3 spatial coordinates, and the boundaries need not be parallel. Their state of development is not as complete.In general, the models which fall within these two subdivisions consider the ocean surface to be a pressure release boundary due to the large mismatch in characteristic impedance between water and air. The water column itself is treated as an ideal fluid J. A. DeSanto (ed.), Ocean Acoustics
The effect of frequency dependence of bottom reflectivity on acoustic transmission in shallow water over a sandy bottom is investigated using transmission loss data from measurements conducted at a wide range of frequencies. Biot’s theory of acoustic wave propagation in fluid-saturated porous media is applied to prediction of bottom reflectivity for a sea bottom consisting of medium grain size sand. For a homogeneous half-space the theory predicts a frequency-dependent bottom reflectivity in contrast to the fluid or solid bottom models. Transmission loss predicted using the Biot model of the sediment shows agreement with measurements at all frequencies considered, which ranged from 100 to 8000 Hz. The fluid model, which assumed a dispersionless velocity and an attenuation that is proportional to frequency, has performed poorly at the low frequency of 100 Hz. [Work supported by Naval Sea Systems Command 06UR1.]
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