一种改进的引力搜索算法及其波束赋形

doi:10.19665/j.issn1001-2400.2020.02.012

Abstract

Abstract:

In view of the adverse effect of the random initial value on the performance and convergence speed of the gravitation search algorithm, a quasi-oppositional gravity search algorithm (QOGSA) is proposed. The quasi-oppositional based learning OBL is embedded into the GSA algorithm, the number of iteration is divided into multiple learning cycle, the oppositional probability is adjusted according to the success rate of the past learning cycle, and an adjustable oppositional probability is designed to optimize the timing of the mechanism in the evolution, which improves the speed of the algorithm to search for the optimal solution greatly. On this basis, in order to improve the population diversity, elite particles are retained to the next generation population. They replace the particles with a poor fitness value and acquire a higher optimization accuracy. Compared with the existing algorithms in the literature, the optimization accuracy of the QOGSA for the average optimal value of the single-peak and multi-peak test functions can be improved by 1016. For the shaping results of different types of beam, the optimization accuracy of the improved algorithm for the sidelobe can be improved from 1.26dB to 5.99dB. On the premise of the fastest convergence speed, the QOGSA can greatly avoid the problem that other optimization algorithms tend to fall into local optimization, with the overall performance being the best.

Key words: gravitational search algorithm, shaped beam synthesis, opposition-based learning, adjustable oppositional probability, elite particles

CLC Number:

TN821+.91

SUN Cuizhen,DING Jun,GUO Chenjiang. Improved gravitational search algorithm for shaped beam forming[J].Journal of Xidian University, 2020, 47(2): 83-90.

Figures/Tables 7

References 13

[1]	薛正辉, 李伟明, 任武 . 阵列天线分析与综合[M]. 北京: 北京航空航天大学出版社, 2011.
[2]	SUN G, LIU Y H, LI H , et al. An Antenna Array Sidelobe Level Reduction Approach through Invasive Weed Optimization[J]. International Journal of Antennas and Propagation, 2018,2018:4867851.
[3]	梁爽, 孙庚, 刘衍珩 . 改进布谷鸟算法用于阵列天线方向图优化[J]. 西安电子科技大学学报, 2019,46(1):174-180.
	LIANG Shuang, SUN Geng, LIU Yanheng . Improved Cuckoo Search Algorithm for Optimizing the Beam Patterns of Linear Antenna Arrays[J]. Journal of Xidian University, 2019,46(1):174-180.
[4]	CUI C, LI W T, YE X T , et al. Hybrid Genetic Algorithm and Modified Iterative Fourier Transform Algorithm for Large Thinned Array Synjournal[J]. IEEE Antennas and Wireless Propagation Letters, 2017,16:2150-2154.
[5]	刘道华, 胡秀云, 赵岩松 , 等. 一种动态分群带熵权的粒子群优化方法[J]. 西安电子科技大学学报, 2018,45(6):75-80.
	LIU Daohua, HU Xiuyun, ZHAO Yansong , et al. Particle Swarm Optimization Method Based on Dynamic Sub-swarms with Entropy Weight[J]. Journal of Xidian University, 2018,45(6):75-80.
[6]	刘燕, 焦永昌, 张亚明 , 等. 混合入侵杂草算法用于阵列天线波束赋形[J]. 西安电子科技大学学报, 2014,41(4):94-99.
	LIU Yan, JIAO Yongchang, ZHANG Yaming , et al. Application of Hybrid Invasive Weed Optimization Algorithm to the Shaped Beam Synjournal of Array Antennas[J]. Journal of Xidian University, 2014,41(4):94-99.
[7]	DAS A, MANDAL D, GHOSHAL S P , et al. Moth Flame Optimization Based Design of Linear and Circular Antenna Array for Side Lobe Reduction[J]. International Journal of Numerical Modelling: Electronic Networks, Devices and Fields, 2019,32(1):e2486.
[8]	ESMAT R, HOSSEIN N, SAEID S . GSA: a Gravitational Search Algorithm[J]. Information Sciences, 2019,179(13):2232-2248.
[9]	SHARMA A, MATHUR S . A Novel Adaptive Beamforming with Reduced Side Lobe Level Using GSA[J]. The International Journal for Computation and Mathematics in Electrical and Electronic Engineering, 2018,37(6):2263-2278.
[10]	MOHANTY S K, MANGARAJ B B . An Optimal Design of Super-directive Dipole Linear Antenna Array Using Gravitational Search Algorithm and Large Perfect Reflecting Surface[J]. Recent Advances in Electrical and Electronic Engineering, 2018,11(2):227-238.
[11]	SHARMA A, MATHUR S, GOWRI R . Adaptive Beamforming for Linear Antenna Arrays Using Gravitational Search Algorithm[J]. Advances in Intelligent Systems and Computing, 2018,624:1159-1169.
[12]	COELHOA L D S, MARIANI V C, TUTKUN N , et al. Magnetizer Design Based on a Quasi-oppositional Gravitional Search Algorithm[J]. IEEE Transactions on Magnetics, 2014,50(2):350-355.
[13]	孙翠珍, 丁君, 兰建锋 , 等. 改进的引力搜索算法用于阵列天线方向图综合[J]. 西北工业大学学报, 2017,35(5):780-785.
	SUN Cuizhen, DING Jun, LAN Jianfeng , et al. Application of the Improved Gravitational Search Algorithm for the Pattern Synjournal of Array Antennas[J]. Journal of Northwestern Polytechnical University, 2017,35(5):780-785.

函数	优化结果	理论值	IGSA	QOGSA
F₁	平均最优值	0	4.03×10^-5	6.23×10^-10
F₁	最优值中位数	0	4.07×10^-5	7.16×10^-10
F₂	平均最优值	0	0.16×10³	7.69×10^-13
F₂	最优值中位数	0	0.15×10³	3.46×10^-13
F₃	平均最优值	0	0.29	0.00916
F₃	最优值中位数	0	0.04	0.00978
F₄	平均最优值	0	0.03	4.06×10^-16
F₄	最优值中位数	0	3.7×10^-13	2.18×10^-16
F₅	平均最优值	1	3.70	0.9896
F₅	最优值中位数	1	2.07	0.9997

参数	期望值	粒子群算法	引力搜索算法	飞蛾扑火算法	IGSA	QOGSA
峰值旁瓣电平值/dB	<-25.00	-21.03	-22.38	-22.57	-24.31	-25.57
主瓣抖动/dB	1.0000	0.8351	0.7647	0.7682	0.7584	0.7315
零功率主瓣角度范围	85°~130°	84.2°~132.4°	83.8°~131.8°	84.2°~132.4°	84.2°~132.4°	83.8°~131°
零功率主瓣展宽/(°)	0.0	3.2	3.0	3.2	3.2	3.2

参数	期望值	粒子群算法	引力搜索算法	飞蛾扑火算法	IGSA	QOGSA
零功率主瓣展宽/(°)	0.5	0.6	0.6	0.6	0.6	0.6
峰值旁瓣电平值1/dB	<-30	-28.13	-29.67	-29.93	-31.35	-34.07
峰值旁瓣电平值2/dB	<-40	-37.65	-39.42	-39.87	-42.16	-43.64

Improved gravitational search algorithm for shaped beam forming

RichHTML

PDF (PC)

Like

Knowledge

Abstract

Cite this article

share this article

Figures/Tables 7

References 13

Related Articles 1

Metrics

Comments

Recommended 10