[1]MA Long,LU Caiwu,GU Qinghua.Cellular and quantum-behaved wolf pack evolutionary algorithm for solving discrete optimization problems[J].CAAI Transactions on Intelligent Systems,2018,13(5):716-727.[doi:10.11992/tis.201705007]
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Cellular and quantum-behaved wolf pack evolutionary algorithm for solving discrete optimization problems

CAAI Transactions on Intelligent Systems[ISSN 1673-4785/CN 23-1538/TP] Volume: 13 Number of periods: 2018 5 Page number: 716-727 Column: 学术论文—机器学习 Public date: 2018-09-05
Title:
Cellular and quantum-behaved wolf pack evolutionary algorithm for solving discrete optimization problems
Author(s):
MA Long LU Caiwu GU Qinghua
School of Management, Xi’an University of Architecture and Technology, Xi’an 710055, China
Keywords:
discrete optimizationquantum-inspired wolf pack algorithmcellular automatadouble strategy methodsliding mode crossoverbinary encodingfunctional analysiswolf pack algorithmquantum rotation angle
CLC:
TP301.6
DOI:
10.11992/tis.201705007
Abstract:
To solve optimization problems in discrete space, a cellular quantum-inspired wolf pack evolutionary algorithm is proposed for solving discrete optimization problems. First, to speed up the global convergence of the algorithm, when generating the diversity of population, the method fully utilizes the double strategy quantum bit initialization method and the sliding mode crossover method to help generate the initial position and candidate wolf, respectively. Then, to accurately describe the distance between the wolf and the prey as well as enhance the traverse range of wolf pack, the methods of the binary encoding and evolution rules of the cellular automata are used to realize precise description and the selection of the quantum rotation angle, respectively. Then to prove the convergence performance of the algorithm, the method fully utilizes the functional analysis to verify the global convergence. Finally, simulation experiment on six benchmark functions was carried out, and the comparison between the wolf pack algorithm and quantum-inspired wolf pack evolutionary algorithm was provided. The results show that the proposed approach has better convergence speed and great global convergence optimization ability.
References:
[1] MECH L D. The wolf:the ecology and behavior of an endangered species[M]. New York:Natural History Press, 1970.
[2] MIRJALILI S, MIRJALILI S M, LEWIS A. Grey wolf optimizer[J]. Advances in engineering software, 2014, 69:46-61.
[3] EMARY E, ZAWBAA H M, HASSANIEN A E. Binary grey wolf optimization approaches for feature selection[J]. Neurocomputing, 2016, 172:371-381.
[4] 吴虎胜, 张凤鸣, 战仁军, 等. 利用改进的二进制狼群算法求解多维背包问题[J]. 系统工程与电子技术, 2015, 37(5):1084-1091 WU Husheng, ZHANG Fengming, ZHAN Renjun, et al. Improved binary wolf pack algorithm for solving multidimensional knapsack problem[J]. Systems engineering and electronics, 2015, 37(5):1084-1091
[5] 吴虎胜, 张凤鸣, 战仁军, 等. 求解0-1背包问题的二进制狼群算法[J]. 系统工程与电子技术, 2014, 36(8):1660-1667 WU Husheng, ZHANG Fengming, ZHAN Renjun, et al. A binary wolf pack algorithm for solving 0-1 knapsack problem[J]. Systems engineering and electronics, 2014, 36(8):1660-1667
[6] SRIKANTH K, PANWAR L K, PANIGRAHI B K, et al. Meta-heuristic framework:quantum inspired binary grey wolf optimizer for unit commitment problem[J]. Computers & electrical engineering, 2017, 14(21):1-18.
[7] MUANGKOTE N, SUNAT K, CHIEWCHANWATTANA S. An improved grey wolf optimizer for training q-Gaussian radial basis functional-link nets[C]//Proceedings of 2014 International Computer Science and Engineering Conference. Khon Kaen, Thailand, 2014:209-214.
[8] 金杉, 金志刚. 基于量子狼群进化的多目标汇聚节点覆盖算法[J]. 电子与信息学报, 2017, 39(5):1178-1184 JIN Shan, JIN Zhigang. Multi-objective sink nodes coverage algorithm based on quantum wolf pack evolution[J]. Journal of electronics & information technology, 2017, 39(5):1178-1184
[9] VON NEUMANN J, BURKS A W. Theory of self-reproducing automata[M]. Urbana:University of Illinois Press, 1966.
[10] 奚茂龙, 孙俊, 吴勇. 一种二进制编码的量子粒子群优化算法[J]. 控制与决策, 2010, 25(1):99-104 XI Maolong, SUN Jun, WU Yong. Quantum-behaved particle swarm optimization with binary encoding[J]. Control and decision, 2010, 25(1):99-104
[11] 张丽娟, 张艳芳, 赵宜宾. 基于元胞自动机的智能疏散模型的仿真研究[J]. 系统工程理论与实践, 2015, 35(1):247-253 ZHANG Lijuan, ZHANG Yanfang, ZHAO Yibin. Simulation research on intelligent evacuation model based on cellular automation[J]. Systems engineering-theory & practice, 2015, 35(1):247-253
[12] 赵知劲, 郑仕链, 尚俊娜, 等. 基于量子遗传算法的认知无线电决策引擎研究[J]. 物理学报, 2007, 56(11):6760-6766 ZHAO Zhijin, ZHENG Shilian, SHANG Junna, et al. A study of cognitive radio decision engine based on quantum genetic algorithm[J]. Acta physica sinica, 2007, 56(11):6760-6766
[13] 鲁宇明, 黎明, 李凌. 一种具有演化规则的元胞遗传算法[J]. 电子学报, 2010, 38(7):1603-1607 LU Yuming, LI Ming, LI Ling. The cellular genetic algorithm with evolutionary rule[J]. Acta electronica sinica, 2010, 38(7):1603-1607
[14] 邱玉霞, 谢克明. 基于泛函分析的思维进化算法收敛性研究[J]. 计算机工程与应用, 2006(22):36-38 QIU Yuxia, XIE Keming. A Study on convergence of mind evolutionary algorithm based on functional analysis[J]. Computer engineering and application, 2006(22):36-38
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