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Języki publikacji
Abstrakty
Energy saving has always been a concern in production scheduling, especially in distributed hybrid flow shop scheduling problems. This study proposes a shuffled frog leaping algorithm with Q-learning (QSFLA) to solve distributed hybrid flow shop scheduling problems with energy-saving(DEHFSP) for minimizing the maximum completion time and total energy consumption simultaneously. The mathematical model is provided, and the lower bounds of two optimization objectives are given and proved. A Q-learning process is embedded in the memeplex search of QSFLA. The state of the population is calculated based on the lower bound. Sixteen search strategy combinations are designed according to the four kinds of global search and four kinds of neighborhood structure. One combination is selected to be used in the memeplex search according to the population state. An energy-saving operator is presented to reduce total energy consumption without increasing the processing time. One hundred forty instances with different scales are tested, and the computational results show that QSFLA is a very competitive algorithm for solving DEHFSP.
Wydawca
Rocznik
Tom
Strony
101--120
Opis fizyczny
Bibliogr. 33 poz., rys.
Twórcy
autor
- School of Mechanical Engineering, Anhui Polytechnic University, Wuhu 241000, China
- AnHui Key Laboratory of Detection Technology and Energy Saving Devices, AnHui Polytechnic University, Wuhu 241000, China
autor
- School of Mechanical Engineering, Anhui Polytechnic University, Wuhu 241000, China
Bibliografia
- [1]J. C. Cai and D. M. Lei. A cooperated shuffled frog-leaping algorithm for distributed energy-efficient hybrid flow shop scheduling with fuzzy processing time. Complex & Intelligent Systems, 7(5):2235–2253, 2021.
- [2]J. C. Cai, R. Zhou, and D. M. Lei. Dynamic shuffled frog-leaping algorithm for distributed hybrid flow shop scheduling with multiprocessor tasks. Engineering Applications of Artificial Intelligence, 90:103540, 2020.
- [3]J. C. Cai, R. Zhou, and D. M. Lei. Fuzzy distributed two-stage hybrid flow shop scheduling problem with setup time: collaborative variable search. Journal of Intelligent & Fuzzy Systems, 38(3):3189–3199, 2020.
- [4]J.C. Cai, D.M Lei, and M. Li. A shuffled frog-leaping algorithm with memeplex quality for bi-objective distributed scheduling in hybrid flow shop. International Journal of Production Research, 59(18):5404–5421, 2020.
- [5]J.C. Cai, D.M Lei, J. Wang, and L. Wang. A novel shuffled frog-leaping algorithm with reinforcement learning for distributed assembly hybrid flow shop scheduling. International Journal of Production Research, 61(4):1233-1251, 2023.
- [6]R.H. Chen, B. Yang, S. Li, and S.l. Wang. A self-learning genetic algorithm based on reinforcement learning for flexible job-shop scheduling problem. Computers & Industrial Engineering, 149:106778, 2020.
- [7]K. Deb, A. Pratap, S. Agarwal, and T. Meyarivan. A fast and elitist multiobjective genetic algorithm: Nsga-ii. IEEE Transactions on Evolutionary Computation, 6(2):182–197, 2002.
- [8]Yu Du, Jun-qing Li, Chao Luo, and Lei-lei Meng. A hybrid estimation of distribution algorithm for distributed flexible job shop scheduling with crane transportations. Swarm and Evolutionary Computation, 62, 2021.
- [9]M. Eusuff, K. Lansey, and F. Pasha. Shuffled frog-leaping algorithm: a memetic meta-heuristic for discrete optimization. Engineering Optimization, 38(2):129–154, 2006.
- [10]J. H. Hao, J. Q. Li, Y. Du, M. X. Song, P. Duan, and Y. Y. Zhang. Solving distributed hybrid flowshop scheduling problems by a hybrid brain storm optimization algorithm. IEEE Access, 7:66879–66894, 2019.
- [11]E. D. Jiang, L. Wang, and Z. P. Peng. Solving energy-efficient distributed job shop scheduling via multi-objective evolutionary algorithm with decomposition. Swarm and Evolutionary Computation, 58, 2020.
- [12]E. D. Jiang, L. Wang, and J. J. Wang. Decomposition-based multi-objective optimization for energy-aware distributed hybrid flow shop scheduling with multiprocessor tasks. Tsinghua Science and Technology, 26(5):646–663, 2021.
- [13]D. M. Lei, L. Gao, and Y. L. Zheng. A novel teaching-learning-based optimization algorithm for energy-efficient scheduling in hybrid flow shop. Ieee Transactions on Engineering Management, 65(2):330–340, 2018.
- [14]D. Lei and T. Wang. Solving distributed two-stage hybrid flowshop scheduling using a shuffled frog-leaping algorithm with memeplex grouping. Engineering Optimization, 52(9):1461–1474, 2019.
- [15]J. Q. Li, J. K. Li, L. J. Zhang, H. Y. Sang, Y. Y. Han, and Q. D. Chen. Solving type-2 fuzzy distributed hybrid flowshop scheduling using an improved brain storm optimization algorithm. International Journal of Fuzzy Systems, 23(4):1194–1212, 2021.
- [16]Y. L. Li, X. Y. Li, L. Gao, and L. L. Meng. An improved artificial bee colony algorithm for distributed heterogeneous hybrid flowshop scheduling problem with sequence-dependent setup times. Computers & Industrial Engineering, 147, 2020.
- [17]Y.L. Li, F. Li, Q.K. Pan, L. Gao, and M. F. Tasgetiren. An artificial bee colony algorithm for the distributed hybrid flowshop scheduling problem. Procedia Manufacturing, 39:1158–1166, 2019.
- [18]Y.L. Li, X.Y. Li, L. Gao, B. Zhang, Q.K. Pan, M. F. Tasgetiren, and Leilei Meng. A discrete artificial bee colony algorithm for distributed hybrid flow-shop scheduling problem with sequence-dependent setup times. International Journal of Production Research, 59(13):3880–3899, 2021.
- [19]C. Lu, L. Gao, Q. K. Pan, X. Y. Li, and J. Zheng. A multi-objective cellular grey wolf optimizer for hybrid flowshop scheduling problem considering noise pollution. Applied Soft Computing, 75:728–749, 2019.
- [20]L. Meng, K. Gao, Y. Ren, B. Zhang, H. Sang, and C. Zhang. Novel milp and cp models for distributed hybrid flowshop scheduling problem with sequence-dependent setup times. Swarm and Evolutionary Computation, 71:101058, 2022.
- [21]L. Meng, Y.g Ren, B. Zhang, J. Li, H. Sang, and C. Zhang. Milp modeling and optimization of energy-efficient distributed flexible job shop scheduling problem. Ieee Access, 8:191191–191203, 2020.
- [22]Z. Pan, D. Lei, and L. Wang. A knowledge-based two-population optimization algorithm for distributed energy-efficient parallel machines scheduling. IEEE Trans Cybern, PP, 2020.
- [23]H. Qin, T. Li, Y. Teng, and K. Wang. Integrated production and distribution scheduling in distributed hybrid flow shops. Memetic Computing, 13(2):185–202, 2021.
- [24]H.X. Qin, Y.Y. Han, B. Zhang, L.L. Meng, Y.P. Liu, Q.K. Pan, and D.W. Gong. An improved iterated greedy algorithm for the energy-efficient blocking hybrid flow shop scheduling problem. Swarm and Evolutionary Computation, 69, 2022.
- [25]W. S. Shao, Z. S. Shao, and D. C. Pi. Multi-objective evolutionary algorithm based on multiple neighborhoods local search for multi-objective distributed hybrid flow shop scheduling problem. Expert Systems with Applications, 183, 2021.
- [26]G. Wang, X. Li, L. Gao, and P. Li. An effective multi-objective whale swarm algorithm for energy-efficient scheduling of distributed welding flow shop. Annals of Operations Research, page in press, 2021.
- [27]J. Wang, D. Lei, and J. Cai. An adaptive artificial bee colony with reinforcement learning for distributed three-stage assembly scheduling with maintenance. Applied Soft Computing, page 108371, 2021.
- [28]J.J. Wang and L. Wang. A bi-population cooperative memetic algorithm for distributed hybrid flow-shop scheduling. IEEE Transactions on Emerging Topics in Computational Intelligence, 5(6):947–961, 2020.
- [29]J.J. Wang and L. Wang. A cooperative memetic algorithm with learning-based agent for energy-aware distributed hybrid flow-shop scheduling. IEEE Transactions on Evolutionary Computation, 2021.
- [30]L. Wang and D. D. Li. Fuzzy distributed hybrid flow shop scheduling problem with heterogeneous factory and unrelated parallel machine: a shuffled frog leaping algorithm with collaboration of multiple search strategies. IEEE Access, 8:214209–214223, 2020.
- [31]K. C. Ying and S. W. Lin. Minimizing makespan for the distributed hybrid flowshop scheduling problem with multiprocessor tasks. Expert Systems with Applications, 92:132–141, 2018.
- [32]B. Zhang, Q. K. Pan, L. Gao, X. Y. Li, L. L. Meng, and K. K. Peng. A multiobjective evolutionary algorithm based on decomposition for hybrid flow-shop green scheduling problem. Computers & Industrial Engineering, 136:325–344, 2019.
- [33]J. Zheng, L. Wang, and J. J. Wang. A cooperative coevolution algorithm for multi-objective fuzzy distributed hybrid flow shop. Knowledge-Based Systems, 194:105536, 2020.
Typ dokumentu
Bibliografia
Identyfikator YADDA
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