非平稳介质中非色散波的费马原理

Proceedings of the Royal Society of London. Series A. Mathematical and Physical Sciences Pub Date : 2004-06-08 DOI:10.1098/rspa.2003.1231

O. Godin, A. Voronovich

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引用次数: 14

摘要

费马定走时原理是求解波在具有时间无关参数的介质中传播的正反问题的有力工具。本文将费马原理推广到支持速度与频率无关的波的非平稳介质中。用来证明旅行时间相对于实际射线轨迹的变形的平稳性的方法是基于变分原理与斜角方程所得到的射线的比较。考虑了非均匀、运动和各向异性介质。建立了一般各向异性、非均匀、非平稳介质中相速度和群速度及其导数的恒等式。结果表明，如果要求所有试验射线同时到达接收机，则在具有时变参数的介质中，实际射线的传播时间和入射线都是固定的。简要讨论了费马原理在非定常介质中的一些推论和应用。

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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Fermat's principle for non–dispersive waves in non–stationary media

Fermat's principle of stationary travel time serves as a powerful tool for solving direct and inverse problems of wave propagation in media with time–independent parameters. In this paper, Fermat's principle is extended to non–stationary media that support waves with frequency–independent velocity. The approach used to prove the stationarity of travel times with respect to deformation of the actual ray trajectory is based on a comparison of the rays that follow from the variational principle with those from the eikonal equation. Inhomogeneous, moving and anisotropic media are considered. The identities that relate phase and group velocities and their derivatives in general anisotropic, inhomogeneous, non–stationary media are established. It is shown that not only the travel time but also the eikonal is stationary on the actual ray in media with time–dependent parameters if all trial rays are required to arrive at the receiver simultaneously. Some corollaries and applications of Fermat's principle in non–stationary media are discussed briefly.

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Proceedings of the Royal Society of London. Series A. Mathematical and Physical Sciences

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期刊介绍： Proceedings A publishes articles across the chemical, computational, Earth, engineering, mathematical, and physical sciences. The articles published are high-quality, original, fundamental articles of interest to a wide range of scientists, and often have long citation half-lives. As well as established disciplines, we encourage emerging and interdisciplinary areas.