电磁学中的Friedlander-Keller射线展开：来自三维任意表面的单色辐射

IF 2.3 4区数学 Q1 MATHEMATICS, APPLIED

European Journal of Applied Mathematics Pub Date : 2022-10-10 DOI:10.1017/s0956792522000249

A. Radjen, R. Tew, G. Gradoni

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引用次数: 0

摘要

将射线理论应用于求解大波数极限下的麦克斯韦方程组的标准方法包括寻求具有（i）振荡指数的解，该振荡指数的相位项在波数上是线性的，并且（ii）具有用该波数的逆幂表示的振幅轮廓。Friedlander–Keller修正在波浪结构的相位中包含了该波数的附加幂，并且在分析某些波浪现象（如蠕变和回音壁波传播）时，该附加项至关重要。然而，其他波动现象需要推广这一理论。本文的目的是为麦克斯韦方程组提供一个“广义”的Friedlander–Keller-ray变换，以获得一组新的波结构不同相位项和振幅的场方程；然后根据符合特定或一般波前的边界数据来求解这些问题。这些例子特别需要这种概括，因为它们不符合经典的射线理论。

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Friedlander-Keller ray expansions in electromagnetism: Monochromatic radiation from arbitrary surfaces in three dimensions

The standard approach to applying ray theory to solving Maxwell’s equations in the large wave-number limit involves seeking solutions that have (i) an oscillatory exponential with a phase term that is linear in the wave-number and (ii) has an amplitude profile expressed in terms of inverse powers of that wave-number. The Friedlander–Keller modification includes an additional power of this wave-number in the phase of the wave structure, and this additional term is crucial when analysing certain wave phenomena such as creeping and whispering gallery wave propagation. However, other wave phenomena necessitate a generalisation of this theory. The purposes of this paper are to provide a ‘generalised’ Friedlander–Keller ray ansatz for Maxwell’s equations to obtain a new set of field equations for the various phase terms and amplitude of the wave structure; these are then solved subject to boundary data conforming to wave-fronts that are either specified or general. These examples specifically require this generalisation as they are not amenable to classic ray theory.

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来源期刊

European Journal of Applied Mathematics 数学-应用数学

CiteScore

4.70

自引率

0.00%

发文量

审稿时长

>12 weeks

期刊介绍： Since 2008 EJAM surveys have been expanded to cover Applied and Industrial Mathematics. Coverage of the journal has been strengthened in probabilistic applications, while still focusing on those areas of applied mathematics inspired by real-world applications, and at the same time fostering the development of theoretical methods with a broad range of applicability. Survey papers contain reviews of emerging areas of mathematics, either in core areas or with relevance to users in industry and other disciplines. Research papers may be in any area of applied mathematics, with special emphasis on new mathematical ideas, relevant to modelling and analysis in modern science and technology, and the development of interesting mathematical methods of wide applicability.