复杂场景散射中心模型化与雷达成像应用

doi:10.12305/j.issn.1001-506X.2021.10.05

摘要/Abstract

摘要：

在复杂场景中, 目标与环境之间的耦合散射会造成雷达图像特征的干扰, 这一问题给雷达目标自动识别与跟踪技术带来了困难, 成为雷达、电磁领域持续关注的热点研究问题。目前, 使用传统的电磁数值计算方法对复杂场景散射问题进行仿真, 所需计算资源巨大, 耗时很长, 而且多限于针对单一类型复合目标, 难以满足实际工程应用需求。针对此问题，提出了复杂场景散射中心模型化的方法, 集成散射中心模型、物理光学法、积分方程法、四路径模型、射线追踪等方法为一体, 实现了复杂场景、群目标雷达成像快速仿真。本文给出了三种有代表性的复杂场景的逆合成孔径雷达成像仿真结果, 验证了本文方法的可行性及泛用性。

关键词: 复杂场景, 散射中心, 四路径, 雷达成像

Abstract:

In complex scenes, the coupled scattering between radar targets and environment will cause interference in radar image features. This problem brings difficulties to radar target automatic recognition and tracking technology, and it is a common research issue in radar and electromagnetic fields. The traditional electromagnetic numerical calculation methods, which are used to simulate the scattering field in complex scenes at present, need huge computing resources and take a long time, and are mostly limited to a single type of composite targets. They are difficult to meet the practical engineering application. Aiming at this problem the technical route of the scattering center modeling in complex sceness introduced. Combining with the scattering center model, physical optics method, integral equation method, four path model, ray tracing method, the rapid simulation of radar imaging of group targets in complex scene is implemented. In order to verify the feasibility and universality of the method, the inverse synthetic aperture radar imaging results of targets in three typical composite scenes are presented.

Key words: complex scene, scattering center, four-paths, radar imaging

中图分类号:

O441

陈彦锡, 郭琨毅, 殷红成, 盛新庆. 复杂场景散射中心模型化与雷达成像应用[J]. 系统工程与电子技术, 2021, 43(10): 2733-2741.

Yanxi CHEN, Kunyi GUO, Hongcheng YIN, Xinqing SHENG. Scattering center modeling and radar imaging application incomplex scenes[J]. Systems Engineering and Electronics, 2021, 43(10): 2733-2741.

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算法	计算参数
算法	面元数	计算时间/s	RCS相似度/%
FEKO-PO	460 800	28 780	86
PO+IEM	3 550	87	86

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