Phase space representation of sound field in the Lake Kinneret

TL;DR

This paper introduces a phase space representation of sound fields in Lake Kinneret, using coherent state expansion to improve predictability and aid in source localization, with potential applications in underwater acoustics.

Contribution

It develops a novel phase space approach for analyzing sound fields in shallow water environments using quantum-inspired coherent state expansion.

Findings

Phase space distribution is less sensitive to environmental disturbances.

The method aligns well with idealized environmental models.

It enables effective source localization and beam isolation.

Abstract

The paper presents the analysis of pulsed sound fields recorded by a vertical array in the Lake Kinneret (Israel). The transition from the traditional representation of the complex amplitude of the received field as a function of depth and time to a function representing the field distribution in the phase space `depth - angle - time' is considered. Due to the absence of multipath and problems with caustics, the sound field distribution in phase space is less sensitive to environmental disturbances and therefore more predictable than in configuration space. The transition is carried out using the coherent state expansion developed in the quantum theory. The found distribution of the field intensity in the phase space agrees with the calculation performed with an idealized environmental model. It is shown that this distribution can be taken as the input for solving the problem of source localization. The results of data processing demonstrate the possibility of using the coherent state expansion for isolating the field component formed by a given beam of rays.