Dynamic cooperative random drift particle swarm optimization algorithm assisted by evolution information

doi:10.11772/j.issn.1001-9081.2020040481

Journal of Computer Applications ›› 2020, Vol. 40 ›› Issue (11): 3119-3126.DOI: 10.11772/j.issn.1001-9081.2020040481

• Artificial intelligence • Previous Articles Next Articles

Dynamic cooperative random drift particle swarm optimization algorithm assisted by evolution information

ZHAO Ji^1,2, CHENG Cheng³

1. Wuxi Research Center for Environmental Science and Engineering, Wuxi Jiangsu 214153, China;
2. School of IoT Engineering, Jiangnan University, Wuxi Jiangsu 214122, China;
3. China Ship Scientific Research Center, Wuxi Jiangsu 214082, China

Received:2020-04-17 Revised:2020-07-13 Online:2020-11-10 Published:2020-07-27
Supported by:
This work is partially supported by the National Natural Science Foundation of China (61672263), the Program of "Qing Lan Project" Young and Middle-aged Academic Leaders in Colleges and Universities of Jiangsu Province (2019), the Program of Young and Middle-aged Academic Leaders of Wuxi Research Center for Environmental Science and Engineering (2018).

演化信息协助的动态协同随机漂移粒子群优化算法

赵吉^1,2, 程成³

1. 无锡环境科学与工程研究中心, 江苏无锡 214153;
2. 江南大学物联网工程学院, 江苏无锡 214122;
3. 中国船舶科学研究中心, 江苏无锡 214082

通讯作者: 赵吉(1980-),女,江苏泰兴人,副教授,博士,主要研究方向:进化计算、人工智能;queenji97@hotmail.com
作者简介:程成(1982-),男,江苏徐州人,高级工程师,硕士,主要研究方向:计算仿真、进化算法
基金资助:
国家自然科学基金资助项目（61672263）；江苏省高校“青蓝工程”中青年学术带头人项目（2019）；无锡环境科学与工程研究中心中青年学术带头人项目（2018）。

Abstract

Abstract: A dynamic Cooperative Random Drift Particle Swarm Optimization (CRDPSO) algorithm assisted by evolution information was proposed in order to improve the population diversity of random drift particle swarm optimization. By using the vector information of context particles, the population diversity was increased by the dynamic cooperation between the particles, to improve the search ability of the swarm and make the whole swarm cooperatively search for the global optimum. At the same time, at each iteration during evolution, the positions and the fitness values of the evaluated solutions in the algorithm were stored by a binary space partitioning tree structure archive, which led to the fast fitness function approximation. The mutation was adaptive and nonparametric because of the fitness function approximation enhanced the mutation strategy. CRDPSO algorithm was compared with Differential Evolution (DE), Covariance Matrix Adaptation Evolution Strategy (CMA-ES), continuous Non-revisiting Genetic Algorithm (cNrGA) and three improved Quantum-behaved Particle Swarm Optimization (QPSO) algorithms through a series of standard test functions. Experimental results show that the performance of CRDPSO is optimal for both unimodal and multimodal test functions, which proves the effectiveness of the algorithm.

Key words: swarm intelligence, dynamic cooperative evolution, evolution information, adaptive nonparametric mutation, Binary Space Partitioning (BSP)

摘要： 为了改善随机漂移粒子群算法的群体多样性，通过演化信息的协助，提出动态协同随机漂移粒子群优化（CRDPSO）算法。利用上下文粒子的向量信息，粒子之间的动态协作增加了种群多样性，这有助于提高群体的搜索能力，并使整个群体协同搜索全局最优值。同时在演化过程中的每次迭代，利用二维空间分割树结构来存储算法中的估计解的位置和适应度值，从而实现快速适应度函数逼近。由于适应度函数逼近增强了变异策略，因此变异是自适应且无参数的。通过典型测试函数将CRDPSO算法和差分进化算法（DE）、协方差矩阵适应进化策略算法（CMA-ES）、非重复访问遗传算法（cNrGA）以及三种改进的量子行为粒子群算法（QPSO）进行比较。实验结果表明，不管是对于单峰还是多峰测试函数，CRDPSO的性能均是最优的，证明了该算法的有效性。

关键词: 群体智能, 动态协同进化, 演化信息, 自适应无参变异, 二维空间分割

CLC Number:

TP301.6

ZHAO Ji, CHENG Cheng. Dynamic cooperative random drift particle swarm optimization algorithm assisted by evolution information[J]. Journal of Computer Applications, 2020, 40(11): 3119-3126.

赵吉, 程成. 演化信息协助的动态协同随机漂移粒子群优化算法[J]. 计算机应用, 2020, 40(11): 3119-3126.

References

[1] KENNEDY J,EBERHART R C. Particle swarm optimization[C]//Proceedings of the 1995 International Conference on Neural Networks. Piscataway:IEEE,1995:1942-1948.
[2] 周文峰, 梁晓磊, 唐可心, 等. 具有拓扑时变和搜索扰动的混合粒子群优化算法[J]. 计算机应用,2020,40(7):1913-1918. (ZHOU W F,LIANG X L,TANG K X,et al. Hybrid particle swarm optimization algorithm with topological time-varying and search disturbance[J]. Journal of Computer Applications,2020,40(7):1913-1918.)
[3] VAN DEN BERGH F,ENGELBRECHT A P. A convergence proof for the particle swarm optimiser[J]. Fundamenta Informaticae, 2010,105(4):341-374.
[4] SUN J, PALADE V, CAI Y, et al. Biochemical systems identification by a random drift particle swarm optimization approach[J]. BMC Bioinformatics,2014,15(S6):No. S1.
[5] OMAR M A. Elementary Solid State Physics:Principles and Applications[M]. Boston:Addison-Wesley,1994:138-169.
[6] SUN J,WU X,PALADE V,et al. Random drift particle swarm optimization algorithm:convergence analysis and parameter selection[J]. Machine Learning,2015,101(1/2/3):345-376.
[7] WU J,ZHANG H,LI J,et al. Scenario based stochastic optimal operated for hybrid energy system with random drift swarm optimization[C]//Proceedings of the 2019 IEEE Congress on Evolutionary Computation. Piscataway:IEEE,2019:1176-1181.
[8] ELSAYED W T,HEGAZY Y G,EL-BAGES M S,et al. Improved random drift particle swarm optimization with self-adaptive mechanism for solving the power economic dispatch problem[J]. IEEE Transactions on Industrial Informatics,2017,13(3):1017-1026.
[9] YANG Z, WU A. A non-revisiting quantum-behaved particle swarm optimization based multilevel thresholding for image segmentation[J]. Neural Computing and Applications,2020,32(16):12011-12031.
[10] ZHANG X,ZHANG X. A non-revisiting artificial bee colony algorithm for phased array synthesis[J]. EURASIP Journal on Wireless Communications and Networking,2017,2017:No. 7.
[11] CHOW C K, YUEN S Y. Continuous non-revisiting genetic algorithm with random search space re-partitioning and one-geneflip mutation[C]//Proceedings of the 2010 IEEE Congress on Evolutionary Computation,Piscataway:IEEE,2010:1-8.
[12] CHOW C K, YUEN S Y. Continuous non-revisiting genetic algorithm with overlapped search sub-region[C]//Proceedings of the 2012 IEEE Congress on Evolutionary Computation. Piscataway:IEEE,2012:1-8.
[13] YUEN S Y,CHOW C K. A genetic algorithm that adaptively mutates and never revisits[J]. IEEE Transactions on Evolutionary Computation,2009,13(2):454-472.
[14] 赵吉, 程成. 基于演化搜索信息的量子行为粒子群优化算法[J]. 计算机工程与应用,2017,53(9):41-46,126.(ZHAO J, CHENG C. Improved QPSO algorithm based on search history[J]. Computer Engineering and Applications, 2017, 53(9):41-46,126.)
[15] CLERC M,KENNEDY J. The particle swarm-explosion, stability,and convergence in a multidimensionalcomplex space[J]. IEEE Transactions on Evolutionary Computation,2002,6(1):58-73.
[16] SUN J,ZHAO J,WU X,et al. Parameter estimation for chaotic systems with a drift particle swarm optimization method[J]. Physics Letters A,2010,374(28):2816-2822.
[17] LI Y, XIANG R, JIAO L, et al. An improved cooperative quantum-behaved particle swarm optimization[J]. Soft Computing,2012,16(6):1061-1069.
[18] LI Y,JIAO L,SHANG R,et al. Dynamic-context cooperative quantum-behaved particle swarm optimization based on multilevel thresholding applied to medical image segmentation[J]. Information Sciences,2015,294:408-422.
[19] KOUMOUSIS V K, KATSARAS C P. A saw-tooth genetic algorithmcombining the effects of variable population size and reinitialization to enhance performance[J]. IEEE Transactions on Evolutionary Computation,2006,10(1):19-28.
[20] YAO X,LIU Y,LIN G. Evolutionary programming made faster[J]. IEEE Transactions on Evolutionary Computation,1999,3(2):82-102.
[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(4):341-359.
[22] HANSEN N. The CMA evolution strategy:a tutorial[EB/OL].[2020-03-06]. https://arxiv.org/pdf/1604.00772.pdf.
[23] 陈伟, 周頔, 孙俊, 等. 一种采用完全学习策略的量子行为粒子群优化算法[J]. 控制与决策,2012,27(5):719-723,730. (CHEN W,ZHOU D,SUN J,et al. Improved quantum-behaved particle swarm optimization algorithm based oncomprehensive learning strategy[J]. Control and Decision,2012,27(5):719-723,730.)

Dynamic cooperative random drift particle swarm optimization algorithm assisted by evolution information

演化信息协助的动态协同随机漂移粒子群优化算法

PDF

Knowledge

Abstract

Cite this article

share this article

References

Related Articles 15

Recommended Articles

Metrics

[1]	FAN Xiaomao, XIONG Honglin, ZHAO Gansen. Cleaning scheduling model with constraints and its solution [J]. Journal of Computer Applications, 2021, 41(2): 577-582.
[2]	LI Kewen, MA Xiangbo, HOU Wenyan. Enhanced fireworks algorithm with adaptive merging strategy and guidance operator [J]. Journal of Computer Applications, 2021, 41(1): 81-86.
[3]	HU Liang, XIAO Renbin, LI Hao. Bee colony double inhibition labor division algorithm and its application in traffic signal timing [J]. Journal of Computer Applications, 2019, 39(7): 1899-1904.
[4]	ZHANG Zhiqiang, LU Xiaofeng, SUN Qindong, WANG Kan. Improved artificial bee colony algorithm with enhanced exploitation ability [J]. Journal of Computer Applications, 2019, 39(4): 949-955.
[5]	ZHANG Xin, ZOU Dexuan, SHEN Xin. Hybrid two-norm particle swarm optimization algorithm with crossover term [J]. Journal of Computer Applications, 2018, 38(8): 2148-2156.
[6]	QI Pan, BAO Kaiyang, MA Xiaoyuan. WSN hierarchical routing algorithm based on fuzzy C-means clustering and swarm intelligence [J]. Journal of Computer Applications, 2018, 38(7): 1974-1980.
[7]	TONG Nan, FU Qiang, ZHONG Caiming. Improved teaching-learning-based optimization algorithm based on self-learning mechanism [J]. Journal of Computer Applications, 2018, 38(2): 443-447.
[8]	YU Dekuang, YANG Yi, QIAN Jun. Dynamic random distribution particle swarm optimization strategy for cloud computing resources [J]. Journal of Computer Applications, 2018, 38(12): 3490-3495.
[9]	ZHAO Yanlong, HUA Nan, YU Zhenhua. Improved particle swarm optimization algorithm based on twice search [J]. Journal of Computer Applications, 2017, 37(9): 2541-2546.
[10]	SUN Jiaze, GENG Guohua. Global optimal matching method for 3D fragments based on swarm intelligence [J]. Journal of Computer Applications, 2016, 36(1): 266-270.
[11]	HE Li, LIU Xiaodong, LI Songyang, ZHANG Qian. Parallel particle swarm optimization algorithm in multicore computing environment [J]. Journal of Computer Applications, 2015, 35(9): 2482-2485.
[12]	XU Xiangping, LU Haiyan, CHENG Biyun. Improved artificial bee colony algorithm based on dynamic evaluation selection strategy [J]. Journal of Computer Applications, 2015, 35(7): 1969-1974.
[13]	YU Changqing WANG zhurong. Producer pre-selection mechanism based on self-adaptive group search optimizer [J]. Journal of Computer Applications, 2013, 33(11): 3102-3106.
[14]	ZHANG Weiping REN Xuefei LI Guoqiang NIU Peifeng. Improved gravitation search algorithm and its application to function optimization [J]. Journal of Computer Applications, 2013, 33(05): 1317-1320.
[15]	HOU Xuemei LIU Wei GAO Fei LI Zhibo WANG Jing. Fuzzy multi-objective software reliability redundancy allocation based on swarm intelligence algorithm [J]. Journal of Computer Applications, 2013, 33(04): 1142-145.