[1]WU Husheng,XIAO Renbin.A new approach to swarm intelligence: role-matching labor division of a wolf pack[J].CAAI Transactions on Intelligent Systems,2021,16(1):125-133.[doi:10.11992/tis.202007043]
Copy

A new approach to swarm intelligence: role-matching labor division of a wolf pack

CAAI Transactions on Intelligent Systems[ISSN 1673-4785/CN 23-1538/TP] Volume: 16 Number of periods: 2021 1 Page number: 125-133 Column: 学术论文—人工智能基础 Public date: 2021-01-05
Title:
A new approach to swarm intelligence: role-matching labor division of a wolf pack
Author(s):
WU Husheng1 XIAO Renbin2
1. College of Equipment Management and Support, Engineering University of PAP, Xi’an 710086, China;
2. School of Artificial Intelligence and Automation, Huazhong University of Science and Technology, Wuhan 430074, China
Keywords:
swarm intelligencewolf packlabor divisiontask allocationself-organizationrole-matchingactivation-inhibitionstimulus-response
CLC:
TP242
DOI:
10.11992/tis.202007043
Abstract:
A novel role-matching labor division method is proposed, inspired by the labor division behavior of a biological wolf pack. First, through in-depth analysis of the biological behavior of natural wolves, the three typical characteristics of the labor division behavior of a wolf pack, i.e., the specialization of individual tasks, the plasticity of individual roles, and the balance of task allocation, are summarized and analyzed in this paper. The bionic mapping relationship between the labor division behavior of a biological wolf pack and the universal task allocation is established. Second, from the perspective of the interactive mode of “individual-individual” plus “individual-environment,” the individual role transformation and task adjustment mechanism of the role-matching labor division of a wolf pack are analyzed deeply in this paper. The flexible role-matching labor division mechanism of a wolf pack is studied, and a new swarm intelligence method is proposed, i.e., the wolf pack role-matching labor division method. Finally, the wolf pack role-matching labor division model, ant colony stimulus-response labor division model, and bee colony activation-inhibition labor division model are compared and analyzed, the proposed method has extensive application prospects in many fields.
References:
[1] ROBINSON G E. Regulation of division of labor in insect societies[J]. Annual review of entomology, 1992, 37(1):637-665.
[2] XIAO Renbin, WANG Yingcong. Labour division in swarm intelligence for allocation problems:a survey[J]. International journal of bio-inspired computation, 2018, 12(2):71-86.
[3] 肖人彬, 王英聪. 群智能自组织劳动分工研究进展[J]. 信息与控制, 2019, 48(2):129-139, 148
XIAO Renbin, WANG Yingcong. Research progress of self-organized labor division in swarm intelligence[J]. Information and control, 2019, 48(2):129-139, 148
[4] PARPINELLI R S, LOPES H S. New inspirations in swarm intelligence:a survey[J]. International journal of bio-inspired computation, 2011, 3(1):1-16.
[5] BESHERS S N, FEWELL J H. Models of division of labor in social insects[J]. Annual review of entomology, 2001, 46(1):413-440.
[6] 王伟嘉, 郑雅婷, 林国政, 等. 集群机器人研究综述[J]. 机器人, 2020, 42(2):232-256
WANG Weijia, ZHENG Yating, LING Guozheng, et al. Swarm robotics:a review[J]. Robot, 2020, 42(2):232-256
[7] TAN Ying, ZHENG Zhongyang. Research advance in swarm robotics[J]. Defence technology, 2013, 9(1):18-39.
[8] KORSAH G A, STENTZ A, DIAS M B. A comprehensive taxonomy for multi-robot task allocation[J]. The international journal of robotics research, 2013, 32(12):1495-1512.
[9] KHAMIS A, HUSSEIN A, ELMOGY A. Multi-robot task allocation:a review of the state-of-the-art[M]. KOUB?A A, MARTíNEZ-DE DIOS J. Cooperative Robots and Sensor Networks 2015. Studies in Computational Intelligence. Cham, Germany:Springer, 2015.
[10] LIU Chun, KROLL A. Performance impact of mutation operators of a subpopulation-based genetic algorithm for multi-robot task allocation problems[J]. SpringerPlu, 2016, 5(1):1361.
[11] GERKEY B P, MATARI? M J. A formal analysis and taxonomy of task allocation in multi-robot systems[J]. The international journal of robotics research, 2004, 23(9):939-954.
[12] WANG Jianping, GU Yuesheng, LI Xiaomin. Multi-robot task allocation based on ant colony algorithm[J]. Journal of computers, 2012, 7(9):2160-2167.
[13] LI Hao, XIAO Renbin, WU Husheng. Modelling for combat task allocation problem of aerial swarm and its solution using wolf pack algorithm[J]. International journal of innovative computing and applications, 2016, 7(1):50-59.
[14] BENI G. From swarm intelligence to swarm robotics[M]. SAHIN E, SPEARS W M. Swarm Robotics. Berlin, Heidelberg:Springer, 2004:1-9.
[15] MECH D L. Alpha status, dominance, and division of labor in wolf packs[J]. Canadian journal of zoology, 1999, 77(8):1196-1203.
[16] 吴虎胜, 张凤鸣, 吴庐山. 一种新的群体智能算法-狼群算法[J]. 系统工程与电子技术, 2013, 35(11):2430-2438
WU Husheng, ZHANG Fengming, WU Lushan. A new swarm intelligence algorithm-wolf pack algorithm[J]. Systems engineering and electronics, 2013, 35(11):2430-2438
[17] MIRJALILI S, MIRJALILI S M, LEWIS A. Grey wolf optimizer[J]. Advances in engineering software, 2014, 69:46-61.
[18] PIEREZAN J, COELHO L D S. Coyote optimization algorithm:a new metaheuristic for global optimization problems[C]//Proceedings of 2018 IEEE Congress on Evolutionary Computation (CEC). Rio de Janeiro, Brazil:IEEE, 2018.
[19] WU Husheng, XIAO Renbin. Flexible wolf pack algorithm for dynamic multidimensional knapsack problems[J]. Research, 2020, 2020:1762107.
[20] MADDEN J D, ARKIN R C, MACNULTY D R. Multi-robot system based on model of wolf hunting behavior to emulate wolf and elk interactions[C]//Proceedings of 2010 IEEE International Conference on Robotics and Biomimetics. Tianjin, China:IEEE, 2010.
[21] MARTíN J, BARJA I, LóPEZ P. Chemical scent constituents in feces of wild Iberian wolves (Canis lupus signatus)[J]. Biochemical systematics and ecology, 2010, 38(6):1096-1102.
[22] NOWAK S, J?DRZEJEWSKI W, SCHMIDT K, et al. Howling activity of free-ranging wolves (Canis lupus) in the Bia?owie?a primeval forest and the western Beskidy Mountains (Poland)[J]. Journal of ethology, 2007, 25(3):231-237.
[23] HEBERLEIN M T E, TURNER D C, RANGE F, et al. A comparison between wolves, Canis lupus, and dogs, Canis familiaris, in showing behaviour towards humans[J]. Animal behaviour, 2016, 122:59-66.
[24] WHITE K A J, LEWIS M A, MURRAY J D. A model for wolf-pack territory formation and maintenance[J]. Journal of theoretical biology, 1996, 178(1):29-43.
[25] WU Husheng, ZHANG Fengming. A uncultivated wolf pack algorithm for high-dimensional functions and its application in parameters optimization of PID controller[C]//Proceedings of the 2014 IEEE Congress on Evolutionary Computation. Beijing, China:IEEE, 2014:1477-1482.
[26] BONABEAU E, THERAULAZ G, DENEUBOURG J L. Quantitative study of the fixed threshold model for the regulation of division of labour in insect societies[J]. Proceedings of the royal society of London. series B:biological sciences, 1996, 263(1376):1565-1569.
[27] BESHERS S N, HUANG Z Y, OONO Y, et al. Social inhibition and the regulation of temporal polyethism in honey bees[J]. Journal of theoretical biology, 2001, 213(3):461-479.
[28] DUARTE A, PEN I, KELLER L, et al. Evolution of self-organized division of labor in a response threshold model[J]. Behavioral ecology and sociobiology, 2012, 66(6):947-957.
[29] 胡亮. 基于激发抑制的群智能劳动分工方法求解动态分配问题[D]. 武汉:华中科技大学, 2019.
HU Liang. Solving dynamic allocation problems by activator-inhibitor based labor division approach in swarm intelligence[D]. Wuhan:Huazhong University of Science and Technology, 2019.
[30] WU Husheng, LI Hao, XIAO Renbin, et al. Modeling and simulation of dynamic ant colony’s labor division for task allocation of UAV swarm[J]. Physica A:statistical mechanics and its applications, 2018, 491:127-141.
[31] 肖人彬, 王英聪. 一种面向时间分配问题的群智能劳动分工新方法[J]. 智能系统学报, 2019, 14(3):438-448
XIAO Renbin, WANG Yingcong. A new approach to labor division in swarm intelligence for time allocation problem[J]. CAAI transactions on intelligent systems, 2019, 14(3):438-448
[32] WANG Yingcong, XIAO Renbin, WANG Huimin. A flexible labour division approach to the polygon packing problem based on space allocation[J]. International journal of production research, 2017, 55(11):3025-3045.
[33] 曹勇, 肖人彬. 蜂群激发抑制与刺激响应相结合的群机器人区域覆盖算法[J]. 复杂系统与复杂性科学, 2019, 16(4):1-12
CAO Yong, XIAO Renbin. Swarm robot region coverage algorithm combined with bee colony activator inhibition with stimulus response[J]. Complex systems and complexity science, 2019, 16(4):1-12
Similar References:

Memo

-

Last Update: 2021-02-25

Copyright © CAAI Transactions on Intelligent Systems