Riemannian Geometric Modeling of Underwater Acoustic Ray Propagation · Basic Theory

IF 0.8 4区物理与天体物理 Q3 PHYSICS, MULTIDISCIPLINARY

物理学报 Pub Date : 2023-01-01 DOI:10.7498/aps.72.20221451

Guo X J, Ma S Q, Zhang L L, Lan Q, Huang C X

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引用次数: 0

Abstract

Underwater sound propagation models are generally established from the extrinsic perspective, that is, embedding acoustic channels in Euclidean space with fixed coordinate system. Riemannian geometry is intrinsic for curved space, that can describe the essential properties of background manifolds. The underwater acoustic Gaussian beam was originally adopted from seismology. Till now it is the most important method used in acoustic ray based modeling and applications. Due to the advantages of Gaussian beam method over the traditional ray counterpart, it is the mainstream technology of ray propagation computational software such as the famous Bellhop. With the assumption of Euclidean space, it is hard to grasp the naturally curved characteristics of the Gaussian beam. In this paper, we propose the Riemannian geometry theory of underwater acoustic ray propagation, and obtain the following results : (1) The Riemannian geometric intrinsic forms of the eikonal equation, paraxial ray equation and the Gaussian beam under radially symmetric acoustic propagation environments are established, that provide a Riemannian geometric interpretation of the Gaussian beam. In fact, the underwater acoustic eikonal equation is equivalent to the geodesic equation in Riemannian manifolds, and the intrinsic geometric spreading of the Gaussian beam corresponds to the lateral deviation of geodesic curve along the Jacobian field. (2) Some geometric and topological properties of acoustic ray about conjugate points and section curvature are acquired by the Jacobi field theory, indicating that the convergence of ray beam corresponds to the intersection of geodesics at the conjugate point with positive section curvature. (3)The specific modeling method under horizontal stratified and distance-related environment is presented using the above theory. And we point out that the method proposed here is also applicable to other radially symmetric acoustic propagation environments. (4) Simulation and comparative analysis of three typical underwater acoustic propagation examples, confirms the feasibility of the Riemannian geometric model for underwater acoustic propagation. And shows that the Riemannian geometric model has exact mathematical physics meaning over the Euclidean space method adopted by the Bellhop model. The basic theory given in this paper can be extended to curved surface, three-dimensional and other complex propagation environments. And especially it lays a theoretical foundation for the further research of long-range acoustic propagation considering curvature of the earth.

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水声射线传播的黎曼几何建模·基础理论

水声传播模型一般是从外在角度建立的，即在固定坐标系的欧氏空间中嵌入声通道。黎曼几何是弯曲空间的固有几何，它可以描述背景流形的基本性质。水声高斯波束最初是从地震学中引入的。它是迄今为止基于声射线的建模和应用中最重要的方法。由于高斯光束法相对于传统射线法的优势，它是著名的Bellhop等射线传播计算软件的主流技术。在欧氏空间假设下，很难把握高斯光束的自然弯曲特性。本文提出了水声射线传播的黎曼几何理论，得到了以下结果:(1)建立了径向对称声传播环境下的对角方程、近轴射线方程和高斯光束的黎曼几何本征形式，给出了高斯光束的黎曼几何解释。实际上，水声方程等价于riemann流形中的测地线方程，高斯波束的本征几何扩展对应于测地线曲线沿雅可比场的横向偏移。(2)利用Jacobi场理论得到了声射线在共轭点和截面曲率处的一些几何和拓扑性质，表明射线束的收敛对应于截面曲率为正的共轭点处测地线的交点。(3)利用上述理论，提出了水平分层和距离相关环境下的具体建模方法。并指出本文提出的方法同样适用于其他径向对称声传播环境。(4)对三个典型水声传播实例进行了仿真和对比分析，证实了黎曼几何模型用于水声传播的可行性。并表明黎曼几何模型比Bellhop模型所采用的欧几里得空间方法具有精确的数学物理意义。本文给出的基本理论可以推广到曲面、三维及其他复杂的传播环境。特别是为进一步研究考虑地球曲率的远程声传播奠定了理论基础。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

物理学报物理-物理：综合

CiteScore

1.70

自引率

30.00%

发文量

31245

审稿时长

1.9 months

期刊介绍： Acta Physica Sinica (Acta Phys. Sin.) is supervised by Chinese Academy of Sciences and sponsored by Chinese Physical Society and Institute of Physics, Chinese Academy of Sciences. Published by Chinese Physical Society and launched in 1933, it is a semimonthly journal with about 40 articles per issue. It publishes original and top quality research papers, rapid communications and reviews in all branches of physics in Chinese. Acta Phys. Sin. enjoys high reputation among Chinese physics journals and plays a key role in bridging China and rest of the world in physics research. Specific areas of interest include: Condensed matter and materials physics; Atomic, molecular, and optical physics; Statistical, nonlinear, and soft matter physics; Plasma physics; Interdisciplinary physics.