Grating Lobe Suppression of Non-Periodic Geometric Formations Based on Modified Particle Swarm Optimization

IF 1.4 4区管理学 Q3 ENGINEERING, ELECTRICAL & ELECTRONIC

Iet Radar Sonar and Navigation Pub Date : 2025-06-14 DOI:10.1049/rsn2.70046

Lin Qiu, Huijie Liu, Juan Chen, Hao Huang, Andrew W. H. Ip, Kai Leung Yung

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引用次数: 0

Abstract

For the issue of configuration difficulty in maintaining linear formations based on the same orbital plane for distributed space-based coherent aperture radar (DSCAR), it is necessary to modify the linear formation model into an arc formation model. This article derives the steering vector and joint pattern expressions for DSCAR based on uniform arc formation, and designs a segmented inertial factor (IF) particle swarm optimization (PSO) to seek the optimal solution for non-uniform spacing and random yaw angle in non-periodic geometric distribution. Simulation analysis shows that the combination of non-uniform spacing and random yaw angle in non-periodic geometric formations can achieve lower peak side lobe level (PSLL) compared to single non-uniform spacing and single random yaw angle but with wider beamwidth spread. Additionally, the segmented IF PSO proposed in this article balances convergence more quickly in the early stage of the search process and improves convergence speed to approach the optimal value (OV) in later stage. Compared with other IF PSO, it has better convergence speed and accuracy.

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基于改进粒子群优化的非周期几何形状光栅瓣抑制

针对分布式天基相干孔径雷达（DSCAR）在同一轨道平面上保持直线编队构型困难的问题，有必要将直线编队模型修正为圆弧编队模型。推导了基于均匀圆弧形成的DSCAR的转向矢量和联合模式表达式，设计了一种分段惯性因子粒子群优化算法，寻求非周期几何分布中非均匀间距和随机偏航角的最优解。仿真分析表明，在非周期几何编队中，非均匀间距和随机偏航角组合比单一非均匀间距和随机偏航角组合可以获得更低的峰值旁瓣电平（PSLL），但波束宽度扩展更宽。此外，本文提出的分段中频粒子群在搜索过程的早期更快地平衡收敛性，并在后期提高收敛速度以接近最优值（OV）。与其他中频粒子群相比，该算法具有更好的收敛速度和精度。

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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来源期刊

Iet Radar Sonar and Navigation 工程技术-电信学

CiteScore

4.10

自引率

11.80%

发文量

137

审稿时长

3.4 months

期刊介绍： IET Radar, Sonar & Navigation covers the theory and practice of systems and signals for radar, sonar, radiolocation, navigation, and surveillance purposes, in aerospace and terrestrial applications. Examples include advances in waveform design, clutter and detection, electronic warfare, adaptive array and superresolution methods, tracking algorithms, synthetic aperture, and target recognition techniques.