A Hybrid Algorithm for Radar Cross Section Calculation of Electrically Large Targets

2021 Signal Processing Symposium (SPSympo) Pub Date : 2021-09-20 DOI:10.1109/spsympo51155.2020.9593337

Zhuo Liu, Xu Zhang, Hai-Peng Wang, Feng Wang

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Abstract

In our previous study, we proposed the bidirectional analytical ray tracing (BART). BART is based on geometrical optics (GO) and physical optics (PO) to calculate the multiple reflections of electromagnetic waves by dividing the target into many small facets, which can calculate the radar cross section (RCS) of electrically large targets quickly. However, GO can only calculate the contribution of incident and reflected field, and cannot solve the diffraction problem such as edge and vertex, which makes the calculation results of BART inaccurate under some angles. The uniform geometrical theory of diffraction (UTD) can compensate for the shortcomings of GO to overcome the failure in the shadow area and the discontinuity at the boundary between shadow area and bright area. A hybrid algorithm combining the BART and UTD is proposed in this paper. UTD is introduced into the BART to solve the problem that there is no electric field in the shadow area and discontinuity at the boundary. While ensuring calculation efficiency, it improves the accuracy of BART in calculating the RCS of electrically large targets.

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电大目标雷达截面计算的混合算法

在我们之前的研究中，我们提出了双向分析射线追踪(BART)。BART基于几何光学(GO)和物理光学(PO)，通过将目标分割成许多小面来计算电磁波的多次反射，可以快速计算出电大目标的雷达截面(RCS)。然而，GO只能计算入射场和反射场的贡献，不能解决边缘和顶点等衍射问题，这使得BART在某些角度下的计算结果不准确。均匀几何衍射理论(UTD)可以弥补GO的缺点，克服阴影区失效和阴影区与明区交界处的不连续。本文提出了一种结合BART和UTD的混合算法。在BART中引入UTD是为了解决阴影区无电场和边界不连续的问题。在保证计算效率的同时，提高了BART计算电大目标RCS的精度。

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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2021 Signal Processing Symposium (SPSympo)

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