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动态环境下的自适应反向扩散演化算法()

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《南京师大学报（自然科学版）》[ISSN:1001-4616/CN:32-1239/N]

卷:: 第43卷
期数:: 2020年04期

页码:: 119-128

栏目:: ·智慧应急信息技术·

出版日期:: 2020-12-30

文章信息/Info

Title:: An Adaptively Reversed Diffuse Evolutionary Algorithmin Dynamic Environments

文章编号:: 1001-4616(2020)04-0119-10

作者:: 曹文梁¹; 康岚兰²; 王石¹; (1.东莞职业技术学院计算机工程系,广东东莞 523808)(2.江西理工大学应用科学学院,江西赣州 341000)

Author(s):: Cao Wenliang¹; Kang Lanlan²; Wang Shi¹; (1.Department of Computer Engineering,Dongguan Polytechnic,Dongguan 523808,China)(2.College of Applied Science,Jiangxi University of Science and Technology,Ganzhou 341000,China)

关键词:: 动态优化; 粒子群优化; 反向扩散; 群间平均马氏距离

Keywords:: dynamic optimization; particle swarm optimization; reversed diffuse; between-swarms average Mahalanobis distance

分类号:: TP181

DOI:: 10.3969/j.issn.1001-4616.2020.04.017

文献标志码:: A

摘要:: 针对传统演化优化算法难以在动态环境下有效地持续跟踪最优解的问题,本文提出了一种自适应反向扩散演化算法(ARDEA)对动态环境进行寻优. 该算法采用多种群策略对最优解进行跟踪,通过设置子种群全局动态监哨点监测环境变化; 并引入一种差分粒子群速度更新公式引导个体在搜索空间内不断寻找最优值; 同时,本文提出了一种新的排斥策略以确保种群多样性,以及种群持续跟踪最优解的搜索能力. 该策略包含两个新方法:其一,采用新提出的群间平均马氏距离判断种群间距离,对于群间距过小的两个子种群进一步通过hill-valley函数判定它们的搜索空间是否重叠,其二,将重叠搜索空间中的劣势子种群通过反向扩散操作(RD)重新初始化. 新算法与当前性能较优的动态优化算法同时作用于移动峰测试问题,结果表明,ARDEA算法在动态环境中能更加有效地跟踪最优解,与其它比较算法而言,表现出较强的鲁棒性和适应性.

Abstract:: To solve the problem that traditional evolutionary optimization algorithm is difficult to effectively keep track of the optimal solution in dynamic environment,this paper proposes an adaptively reversed diffuse evolutionary algorithm(ARDEA). The new algorithm adopts the multi-population strategy to track the optimal solution and monitors the environmental changes by setting the global dynamic sentryin each subgroup. A differential particle swarm velocity update formula is introduced to guide individuals to search for the optimal points in the search space. Meanwhile,in order to ensure the diversity of the population and the search efficiency of the sub-population,a new exclusion strategy is proposed in this paper. This strategy includes two method. Firstly,it uses between-swarms average Mahalanobis distance to judge the inter-population distance. If the distance is too small between two sub-populations,hill-valley function is used to further determine whether they tracked the same peak or not. Secondly,the subpopulations with poor performance in the search overlap will be reinitialized by reverse diffusion operation(RD). The new algorithm is compared with several state-of-artdynamic optimization algorithms on moving peak problem. The results show that the ARDEA algorithm can track the optimal solution more effectively in the dynamic environment. Compared with other algorithms,the ARDEA algorithm shows strong robustness and adaptability.

参考文献/References:

[1] LI Q Y,ZOU J,YANG S X,et al.. A predictive strategy based on special points for evolutionary dynamic multi-objective optimization[J]. Soft computing,2019,23(11):3723-3739.
[2]MAURIZIO F,LIBERATI D E,GUALANDI S,et al. Quantum-inspired evolutionary multiobjective optimization for a dynamic production scheduling approach[J]. Multidisciplinary approaches to neural computing,2018,69:191-201.
[3]简琤峰,陈家炜,张美玉. 面向边缘计算的改进混沌蝙蝠群协同调度算法[J]. 小型微型计算机系统,2019,40(11):2424-2430.
[4]YANG C,DING J. Constrained dynamic multi-objective evolutionary optimization for operational indices of beneficiation process[J]. Journal of intelligent manufacturing,2019,30:2701-2713.
[5]YANG S X,YAO X. Evolutionary computation for dynamic optimization problem[M]. Boston:Spring-Verlag Berlin Heidelberg,2013.
[6]CRUZ C,GONZáLEZ J R,PELTA D A. Optimization in dynamic environments:a survey on problems,methods and measures[J]. Soft computing,2011,15(7):1427-1488.
[7]YAZDANI D,NGUYEN T T,BRANKE J,et al. A multi-objective time-linkage approach for dynamic optimization problems with previous-solution displacement restriction[J]. Lecture notes in computer science,2018,10784:864-878.
[8]申鼎才,胡声洲. 基于领域搜索的粒子群动态优化算法[J]. 合肥工业大学学报,2017,40(5):628-632.
[9]LI C H,YANG S X. A clustering particle swarm optimizer for dynamic optimization[C]//Proceedings of the IEEE Comgress on Evolutionary Computation,Trondheim,Norway,2009,May:18-21.
[10]BRANKE J. Memory enhanced evolutionary algorithms for changing optimisation problems[C]//IEEE congress on evolutionary computation,Washington,DC,USA,1999:1875-1882.
[11]CAO L,XU L,GOODMAN E D. A neighbor-based learning particle swarm optimizer with short-term and long-term memory for dynamic optimization problems[J]. Information sciences,2018,453:463-485.
[12]LI C,YANG S. A clustering particle swarm optimizer for dynamic optimization[C]//Proceedings of the IEEE Congress on Evolutionary Computation,2009:439-446.
[13]YANG S,LI C. A clustering particle swarm optimizer for locating and tracking multiple optima in dynamic environments[J]. IEEE Transations on Evolutionary Computation,Proceedings of the IEEE Congress on Evolutionary Computation,2010,6(10):959-974.
[14]卜晨阳. 演化约束优化及演化动态优化求解算法研究[D]. 合肥:中国科学技术大学,2017.
[15]李志坚. 改进的差分演化算法及其在动态优化问题中的应用[D]. 武汉:华中师范大学,2016.
[16]HUI S,SUGANTHAN P N. Ensemble differential evolution with dynamic subpopulations and adaptive clearing for solving dynamic optimization problems[C]//IEEE congress on evolutionary computation. Brisbane,Australia,2012:1-8.
[17]MENDES R,MOHAIS A S. DynDE:a differential evolution for dynamic optimization problems[C]//IEEE Congress on Evolutionary Computation,Edinburgh,UK,2005:2808-2815.
[18]BREST J,ZAMUDA A,BOSKOVIC B,et al. Dynamic optimization using self-adaptive differential evolution[C]//IEEE Congress on Evolutionary Computation,Trondheim,Norway,2009:415-422.
[19]KENNEDY J,EBERHART R C. Particle swarm optimization[C]//Proceedings of IEEE International Conference on Neural Networks. Perth,Australia,1995:1942-1948.
[20]康岚兰,董文永,宋婉娟,等. 无惯性自适应精英变异反向粒子群优化算法[J]. 通信学报,2017,38(8):66-78.
[21]STORN R,PRICE K. Differential evolution—a simple and efficient heuristic for global optimization over continuous spaces[J]. Journal of global optimization,1997,11:341-359.
[22]周新宇,吴志健,王晖,等. 一种精英反向学习的粒子群优化算法. 电子学报,2013,41(8):1647-1652.
[23]BLACKWELL T,BRANKE J. Multi-swarm optimization in dynamic environments[C]//Applications of Evolutionary Computing. Coimbra,Porugal,2004:489-500.
[24]谢修娟,李香菊,莫凌飞. 基于改进K-means算法的微博舆情分析研究[J]. 计算机工程与科学,2018,40(1):155-158.
[25]ZU Z W,LI Q. Mahalanobis distance fuzzy clustering algorithm based on particle swarm optimization[J]. Journal of Chongqing University of posts and telecommunications(natural science edition),2019,31(2):275-284.
[26]ZUO X,XIAO L. A DE and PSO based hybrid algorithm for dynamic optimization problems[J]. Soft computing,2014,18:1405-1424.
[27]LI C,YANG S,NGUYEN T T,et al. Benchmark Generator for the CEC’2009 Competition on Dynamic Optimization[R]. University of Leicester,University of Birmingham,Honda Research Institute Europe,Vorarlberg University of Applied Sciences,Nanyang Technological University,Technical Report,October 26,2008:1-14.
[28]HAN D P,KIRSTEN E,JAN C B,et al. A survey of dynamic parameter setting methods for nature-inspired swarm intelligence algorithms[J]. Neural computing and applications. 2020,32:567-588.

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备注/Memo

备注/Memo:: 收稿日期:2020-07-08.
基金项目:广东省普通高校特色创新(自然科学)项目(2019GKTSCX142、2017GKTSCX101)、东莞职业技术学院示范建设专项资金项目(政201803)、江西省科技厅自然科学基金面上项目(20202BABL202032)、江西省教育厅科技项目(GJJ181511).
通讯作者:康岚兰,博士,讲师,研究方向:演化计算、机器学习. E-mail:victorykll@163.com

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