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物理绕射理论奇异性研究

Study on singularity of physical theory of diffraction
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摘要 物理绕射理论是计算尖劈绕射的重要方法,其重要意义是消除了几何绕射理论所带来的奇异值。本文导出了这两种绕射系数的另一种表达式,可以非常明确地说明奇异值消除情况。将绕射系数写成余切函数的形式,奇异点就体现在宗量为0的情形,这种情形恰好就是入射边界或反射边界。物理绕射理论在绝大多数情况下消除了几何绕射理论带来的奇异值。但在一种特殊情形下,仍然存在着奇异,即绕射波沿着劈面且双站角为180°。这种奇异会导致在有些情形下,双站散射计算误差非常大,而在单站情形不会发生奇异。最后,通过二维方柱和三角形柱的散射算例进行了相关验证。 Physical theory of diffraction (PTD) is an important method in calculating wedge's diffraction whose advantage is eliminating the singularity of geometric theory of diffraction (GTD). Another expression of the diffraction factors is introduced that may clearly imply the singularity. The diffraction factor is transformed into an arc tangent function whose singularity is zero and the singularity happens to he in incident hounds and re- flection bounds. The PTD eliminates most of the GTD's singularities, but they still appear under a very special situation. This situation is that scattering wave incidents on the wedge and the bi-static angle is 180°. The sin- gularity may induce a very huge error in bi-static scattering calculation. But in mono-static, there is no sigulari- ty. The examples of 2-dimensional square and triangle's scattering problems validate the analytical result.
作者 姬金祖 黄沛霖 刘波 王岩
机构地区 北京航空航天大学航空科学与工程学院
出处 《系统工程与电子技术》 EI CSCD 北大核心 2012年第10期1987-1993,共7页 Systems Engineering and Electronics
基金 总装备部武器装备预先研究资助课题
关键词 计算电磁学 物理绕射理论 奇异值 入射边界 computational electromagnetics physical theory of diffraction ( PTD ) singularity incident boundary
分类号 V218 [航空宇航科学与技术—航空宇航推进理论与工程]
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参考文献12

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系统工程与电子技术
2012年 第10期

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