Bayesian learning based elitist nondominated sorting algorithm for a kind of multi-objective integrated production scheduling and transportation problem

被引：0

作者：

Li, Zuocheng ^{[1
,2
]}

Ding, Ziqi ^{[1
,2
]}

Qian, Bin ^{[1
,2
]}

Hu, Rong ^{[1
,2
]}

Luo, Rongjuan ^{[3
]}

Wang, Ling ^{[4
]}

机构：

[1] Kunming Univ Sci & Technol, Fac Informat Engn & Automat, Kunming 650500, Peoples R China

[2] Kunming Univ Sci & Technol, Higher Educ Key Lab Ind Intelligence & Syst Yunnan, Kunming 650500, Peoples R China

[3] Yunnan Univ Finance & Econ, Sch Logist & Management Engn, Kunming 650221, Peoples R China

[4] Tsinghua Univ, Dept Automat, Beijing 100084, Peoples R China

来源：

APPLIED SOFT COMPUTING | 2025年 / 169卷

基金：

中国国家自然科学基金;

关键词：

Production scheduling; Transportation; Multi-objective optimization; Bayesian learning; Probability model; OPTIMIZATION ALGORITHM; NSGA-II; GENETIC ALGORITHM; LOCAL SEARCH; DELIVERY; MAKESPAN; LEVEL;

D O I：

10.1016/j.asoc.2024.112537

中图分类号：

TP18 [人工智能理论];

学科分类号：

081104 ; 0812 ; 0835 ; 1405 ;

摘要：

This paper focuses on a kind of multi-objective integrated production scheduling and transportation problem (MIPSTP), which is encountered in many real-life industrial processes. MIPSTP contains a production stage for processing products and a transportation stage for transporting products. In MIPSTP, we consider a dedicated integration of distributed scheduling and transportation regarding the two stages, arising from a practical project for a cooperative iron and steel company. The objective of MIPSTP is to minimize the total completion time of each factory and total transportation cost. To solve the problem, a Bayesian learning-based elitist nondominated sorting algorithm (BLENSA) is proposed. The primary highlights of this work are two-fold: 1) new solution structures of MIPSTP and 2) novel search model of BLENSA. For the solution structures, we propose for the first time the mathematical description of MIPSTP, accounting for several features in applications and so is different from conventional scheduling problems. For the search model of BLENSA, we propose a Bayesian learning-based probability model to learn valuable knowledge about nondominated solutions. Thereby, BLENSA combines the Bayesian learning-based probability model to produce a candidate population (CP) and the nondominated sorting method to generate a main population (MP). Next, we propose a greedy competition strategy to construct MP from CP and MP for the next generation. Results of experiments on 57 test instances and a real-life case study demonstrate the effectiveness and practical values of BLENSA.

引用

页数：26

共 65 条

[1]

Gharaei A., Jolai F., A multi-agent approach to the integrated production scheduling and distribution problem in multi-factory supply chain, Appl. Soft Comput., 65, pp. 577-589, (2018)

[2]

Aminzadegan S., Tamannaei M., Fazeli M., An integrated production and transportation scheduling problem with order acceptance and resource allocation decisions, Appl. Soft Comput., 112, (2021)

[3]

Wen X., Wang K., Li H., Sun H., Wang H., Jin L., A two-stage solution method based on NSGA-II for Green Multi-Objective integrated process planning and scheduling in a battery packaging machinery workshop, Swarm Evolut. Comput., 61, (2021)

[4]

Karimi N., Davoudpour H., A branch and bound method for solving multi-factory supply chain scheduling with batch delivery, Expert Syst. Appl., 42, pp. 238-245, (2015)

[5]

Gharaei A., Jolai F., A Pareto approach for the multi-factory supply chain scheduling and distribution problem, Oper. Res., 21, pp. 2333-2364, (2021)

[6]

Mohammadi S., Al-e-Hashem S.M.J.M., Rekik Y., An integrated production scheduling and delivery route planning with multi-purpose machines: a case study from a furniture manufacturing company, Int. J. Prod. Econ., 219, pp. 347-359, (2020)

[7]

Feng X., Xu Z., Integrated production and transportation scheduling on parallel batch-processing machines, IEEE Access, 7, pp. 148393-148400, (2019)

[8]

Meng T., Pan Q., Wang L., A distributed permutation flow-shop scheduling problem with the customer order constraint, Knowl. -Based Syst., 184, (2019)

[9]

Ganji M., Kazemipoor H., Hadji Molana S.M., Sajadi S.M., A green multi-objective integrated scheduling of production and distribution with heterogeneous fleet vehicle routing and time windows, J. Clean. Prod., 259, (2020)

[10]

Tang L., Li F., Chen Z., Integrated scheduling of production and two-stage delivery of make-to-order products: offline and online algorithms, Inf. J. Comput., 31, pp. 493-514, (2019)

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