• 学术论文 •

### 两源交叉眼与多源线阵交叉眼的干扰性能分析

1. 海军工程大学舰船综合电力国防科技重点实验室，湖北 武汉 430033
• 收稿日期:2020-08-15 修回日期:2021-06-14 出版日期:2021-12-25 发布日期:2021-12-25
• 作者简介:周 亮 男,1989年生于湖北黄冈.现为海军工程大学舰船综合电力技术国防科技重点实验室助理研究员.主要研究方向为电子对抗、装备综合保障.E-mail:zh201314l@163.com
刘永才 男,1988年生于黑龙江哈尔滨.现为海军工程大学舰船综合电力技术国防科技重点实验室助理研究员.主要研究方向为电子对抗.E-mail:leonudt@163.com
孟 进（通讯作者） 男,1979年生于河南南阳.现为海军工程大学舰船综合电力技术国防科技重点实验室教授.主要研究方向为电磁攻防.E-mail:mengjinemc@163.com
杨浩楠 男,1996年生于山西怀仁.现为海军工程大学舰船综合电力技术国防科技重点实验室博士研究生.主要研究方向为电子对抗.E-mail:18220526812@163.com
• 基金资助:
国家自然科学基金(71801220)

### Interference Performance Analysis of Two Source Retro-Directive Cross-Eye Jamming and Multi-Source Linear Array Retro-Directive Cross-Eye Jamming

ZHOU Liang, LIU Yong-cai, MENG Jin, YANG Hao-nan

1. National Key Laboratory for Vessel Integrated Power System Technology，Naval University of Engineering，Wuhan，Hubei 430033，China
• Received:2020-08-15 Revised:2021-06-14 Online:2021-12-25 Published:2021-12-25

Abstract:

Cross eye jamming is one of the most effective jamming methods for monopulse radar, and cross eye gain is an important index to measure the performance of cross eye jamming. Based on the gain models of two source retro-directive cross-eye jamming(TRCJ) and linear array multi-source retro-directive cross-eye jamming(LMRCJ), the maximum gain value of LMRCJ under the same amplitude ratio is deduced by taking the cross eye interference of 4-source linear array as an example, and the calculation method of overall phase tolerance of LMRCJ is proposed. Considering the phase control mode between different loops of LMRCJ, amplitude phase fluctuation and platform echo, the gain value and amplitude compatibility limit of LMRCJ and TRCJ are compared and analyzed. The simulation results show that， without considering the platform echo, the maximum gain of TRCJ is not lower than that of LMRCJ under the same amplitude ratio, and the phase tolerance of TRCJ is more relaxed than that of LMRCJ when the gain is high; when the amplitude and phase control capabilities of LMRCJ and TRCJ are the same and weak, the gain of LMRCJ is higher than that of TRCJ; when considering the platform echo, the gain and phase tolerance of LMRCJ and TRCJ are consistent with those of isolating platform echo at high JSR. The paper can provide guidance for the engineering design of the cross-eye jammer.