用于精确干扰波形设计的高效流形算法

doi:10.19665/j.issn1001-2400.20231001

Abstract

Abstract:

Precision jamming is a new concept in the field of electronic warfare.The core idea is to adopt a group of drone swarms equipped with jammers as ultra-sparse arrays to transmit the jamming waveform,which aims to implement blanket jamming to the opponent equipment in the spatial domain precisely and ensures that the friendly equipment is not being affected.However,the existing methods apply only to some specific scenarios,and they need to be improved in computational efficiency.In this case,this paper proposes an efficient waveform design algorithm based on the complex circle manifold to improve the computational efficiency,which can control the energy level in the target and friendly regions according to the practical requirement.First,we establish a novel multi-objective optimization problem(MOP) with unimodular constraints according to the precision jamming geometric model and the worst case of jamming energy distribution in the spatial domain.Then,we adopt the L_p-norm to smooth and approximate the minimax objective function.Finally,the MOP with unimodular constraints is viewed as an unconstrainted problem under the complex circle manifold from the perspective of the Riemann geometry,with the Riemannian Conjugate Gradient(RCG) algorithm employed to solve the problem efficiently.Simulation results are provided to demonstrate that the proposed algorithm can control the energy level in different regions by adjusting the regularization parameter,which meets the requirement of different scenarios and tasks of precision jamming.Moreover,it has a lower computational complexity and improves the computational efficiency for the precision jamming waveform design as compared to the existing methods.

Key words: precision jamming, waveform design, complex circle manifold, multi-objective optimization

CLC Number:

TN972

ZHANG Boyang, CHU Yi, YANG Zhongping, ZHOU Qingsong. Efficient manifold algorithm for the waveform design for precision jamming[J].Journal of Xidian University, 2023, 50(6): 84-92.

Figures/Tables 6

References 19

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参数符号	参数设置	含义
Ω/m	[-50,50]×[-50,50]	xOy平面内关注范围
r_T/m	(0,0,0)	目标设备中心位置
r_P1/m	(20,25,0)	第1个友方设备中心位置
r_P2/m	(-20,10,0)	第2个友方设备中心位置
r_P3/m	(-15,-25,0)	第3个友方设备中心位置
r_P4/m	(10,-20,0)	第4个友方设备中心位置
r_T/m	5	目标区域半径
r_P/m	2	友方区域半径
Δ/m	0.25×0.25	区域离散网格尺寸
M/个	30	无人机蜂群数量
H/m	1 000	无人机蜂群距xOy平面高度
f₀/GHz	1	发射信号载频
N	32	波形长度
p	10	RCG算法中L_p范数的超参数

	SDP+CD算法	MM算法	RCG算法ρ=10¹⁷	RCG算法ρ=10²¹
目标区域最小能量	21.888 1	16.836 2	21.576 8	20.643 1
友方区域最大能量	12.126 5	15.312 0	11.447 0	7.505 2

Efficient manifold algorithm for the waveform design for precision jamming

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References 19

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