Fuzzy multi-objective programming to optimize closed-loop supply chain problem considering cloud management

Document Type : Research Paper

Author

department of industrial engineering, faculty of basic science and engineering, Kosar university of Bojnord, Bojnord, Iran.

10.22070/jqepo.2024.17389.1251

Abstract

 Nowadays, competition is growing therefore, it is essential to try to form proper communications
and reduce the price of the production along with increasing its quality. A supply chain, especially a closedloop supply chain (CLSC) is a good solution in this situation since it has absorbed the attention of managers,
manufacturers and researchers. In this paper, a new fuzzy multi-objective closed-loop supply chain is
formulated. The first objective function increases profit, the second objective function increases cloud
management of total centers of the supply chain, and the third objective function decreases total
environmental impacts. The LP-metric method is used to solve the multi-objective model, validating it with
numerical examples, and sensitivity analysis is done on demand and price parameters. 

Keywords

References

 Abdolazimi, O., Salehi Esfandarani, M., Salehi, M., & Shishebori, D. (2020). A Comparison of Solution Methods for the MultiObjective Closed Loop Supply Chains. Advances in Industrial Engineering, 54(1), 75-98.
Aghagolnezhad Gerdrodbari, M., Harsej, F., Sadeghpour, M., & Molani Aghdam, M. (2021). A green closed-loop supply chain for production and distribution of perishable products. Journal of Quality Engineering and Production Optimization, 6(1), 189-214.

Alinezhad, M. (2019). A new multi-product closed-loop supply chain network design in dairy industry. Iranian Journal of
Operations Research, 10(1), 85-101.

Afshar, M., Hadji Molana, S. M., & Rahmani Parchekelaei, B. (2022). Developing multi-objective mathematical model of
sustainable multi-commodity, multi-level closed-loop supply chain network considering disruption risk under uncertainty.
Journal of Industrial and Systems Engineering, 14(3), 280-302

Amirian, S., Amiri, M., & Taghavifard, M. T. (2022). Sustainable and reliable closed-loop supply chain network design: Normalized normal constraint (NNC) method application. Journal of Industrial and Systems Engineering, 14(3), 33-68.

Ameli, M., Haghighatpanah, S., Davari-Ardakani, H., & Ghasemi S. S. (2022). Bi-objective Stochastic Programming Model for Green Closed-loop Supply Chain Network Design in Presence of Sale and Leaseback Transactions. International Journal of Supply and Operations Management. 9(4), 417-447.

Battaïa, O., Guillaume, R., Krug, Z., & Oloruntoba, R. (2023). Environmental and social equity in network design of sustainable closed-loop supply chains. International Journal of Production Economics, 264, 108981.

Bahrampour, P., Najafi, s. E., Hosseinzadeh Lotfi, f., & Edalatpanah, S. A. (2023). Development of scenario-based mathematical model for sustainable closed loop supply chain considering reliability of direct logistics elements. Journal of Quality Engineering and Production Optimization, 7(2), 232-266. 
 Chaising, S., & Haasis, H. D. (2021). Cloud computing for logistics and procurement services for SMEs and raw material suppliers. International Journal of Logistics Systems and Management, 38(4), 459-474.

Ghahremani-Nahr, J., Nozari, H., & Najafi, S. E. (2020). Design a Green Closed Loop Supply Chain Network by Considering
Discount under Uncertainty. Journal of Applied Research on Industrial Engineering, 7(3) , 238–266.

Goli, A., Golmohammadi, A. M. (2022). Multi-objective Optimization of Location and Distribution in a Closed-loop Supply Chain by Considering Market Share in Competitive Conditions. International Journal of Supply and Operations Management, 9(4),483-495.

Goli, A. (2023). Integration of blockchain-enabled closed-loop supply chain and robust product portfolio design. Computers & Industrial Engineering, 179, 109211.

Javadi Gargari, F., Amoozad-Khalili, H., & Tavakkoli-Mogaddam, R. (2021). Fuzzy Multi-Objective Scenario-based Stochastic Programming to Optimize Supply Chain. Iranian Journal of Operations Research, 12(2), 54-72.

Jolai, F., Hashemi, P., Heydari, J., Bakhshi, A., Keramati, A. (2021). Optimizing a Reverse Logistics System by Considering
Quality of Returned Products. Advances in Industrial Engineering, 54(2), 165-184.

Keshavarzfard, R., & Zamani, B. (2022). A Sustainable Competitive Supply Chain Design Considering Uncertainty of Demand (Case Study in the Battery Manufacturing Industry). Advances in Industrial Engineering, 56(2), 115-138.

Keshmiry zadeh, K., Harsej, F., sadeghpour, M., & Molani Aghdam, M. (2021). A multi-objective multi-echelon closed-loop supply chain with disruption in the centers. Journal of Quality Engineering and Production Optimization, 6(2),31-58.

Khorshidvand, B., Soleimnai, H., Seyyed Esfahani, M. M., & Sibdari, S. (2021). Sustainable closed-loop supply chain network: Mathematical modeling and Lagrangian relaxation. Journal of Industrial Engineering and Management Studies. 8(1), 240-260.

Mezzio, S., Stein, M. & Campitelli, V. (2023). In Cloud Governance: Basics and Practice. Berlin, Boston: De Gruyter, 287-288.
https://doi.org/10.1515/9783110755374-025

Hung, C. W. (2018). Chapter of Cloud Computing-Technology and Practices. Edited by Dinesh G. Harkut, Kashmira N. Kasat and Saurabh A. Shah. DOI: 10.5772/intechopen.77283.

Mirmajlesi, S. R., Shafaei, R., Roghanian, E., & Bashirzadeh, R. (2022). Proposing a multi-objective multi-echelon closed-loop supply chain model with the possibility of partial disruption in distribution centers and maximizing network reliability. Journal of Industrial and Systems Engineering, 14(2), 61-85.

Moubed, M., & Zare Mehrjerdi, Y. (2015). A Robust Modeling of Inventory Routing in Collaborative Reverse Supply Chains.
Iranian Journal of Operations Research, 6(1), 15-33.

Razmjooei, V., Mahdavi , I., Paydar, M. M., (2022). A Fuzzy Bi-objective Optimization Algorithm, International Journal of Supply and Operations Management, 9(3), 360-378.

Shahedi, T., Aghsami, A., & Rabbani, M. (2021). Designing a green closed-loop supply chain network for the automotive tire industry under uncertainty. Journal of Industrial and Systems Engineering, 13(4), 226-261.

Saffarian, M., Mostafayi, S., Kazemi, S. M., & Niksirat, M. (2021). A two-level pricing-inventory-routing problem in green closedloop supply chain: Bi-level programming and heuristic method. Journal of Industrial and Systems Engineering, 13(4), 62-80

Scheller, C., Schmidt, K., & Spengler, T. S. (2023). Effects of network structures on the production planning in closed-loop supply chains–A case study based analysis for lithium-ion batteries in Europe. International Journal of Production Economics, 262, 108892. 
 Wang, Z., Wang, Y., Li, B., & Cheng, Y. (2023). Responsibility sharing strategy of product ecological design and collection in manufacturer-retailer closed-loop supply chain. Computers & Industrial Engineering, 176, 108926.

Yang, Y., Lin, J., Hedenstierna, C. P. T., & Zhou, L. (2023). The more the better? The impact of the number and location of product recovery options on the system dynamics in a closed-loop supply chain. Transportation Research Part E: Logistics and Transportation Review, 175, 103150.

Yousefi-Babadi, A., Soleimani, N., & Shishebori, D. (2021). Capacitated Sustainable Resilient Closed-Loop Supply Chain Network Design: A Heuristics Algorithm. Advances in Industrial Engineering, 55(4), 447-479. 
Journal of Quality Engineering and Production Optimization
Volume 9, Issue 1
May 2024
Pages 47-64

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