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Optimizing Supply Chain Design for Sustainability and Reliability: A Comparative Study of Augmented Epsilon and Normalized Normal Constraint Methods | ||
Control and Optimization in Applied Mathematics | ||
مقاله 6، دوره 9، شماره 1، مرداد 2024، صفحه 97-130 اصل مقاله (2.41 M) | ||
نوع مقاله: Research Article | ||
شناسه دیجیتال (DOI): 10.30473/coam.2023.67540.1230 | ||
نویسندگان | ||
Sajad Amirian؛ Maghsoud Amiri* ؛ Mohammad Taghi Taghavifard | ||
Department of Industrial Management, Faculty of Management and Accounting, Allameh Tabataba’i University, Tehran, Iran. | ||
چکیده | ||
Integrating sustainability and reliability represents a synergistic approach that can be explored through the problem of a closed-loop supply chain network design (SCND). This study is conducted in three stages: mathematical modeling, model solution using exact methods, and evaluation of the solution methods. In the first stage, a mixed-integer linear programming (MILP) model is developed in a multi-objective, multi-product, and multi-period framework. The objectives of the proposed model aim to maximize profitability, social responsibility, and reliability. In the second stage, two methods, namely Augmented $\varepsilon$-Constraint (AEC) and Normalized Normal Constraint (NNC), are implemented in the GAMS software to solve the model and identify the optimal Pareto solutions. In the third stage, the Shannon Entropy technique is employed to determine the criteria weights, and the VIKOR technique is utilized to select the superior solution method. The overall performance accuracy of the proposed model is measured using four samples from a numerical example with randomly generated data based on the objective function coefficients. The results indicate the presence of a conflict among the three objective functions. Consequently, decision-makers should consider sacrificing some profitability to enhance environmental protection and improve reliability. In terms of three criteria, run time, diversification metric, and general distance, the NNC method is given priority over the AEC method. Even when the criteria are given equal weight, the superiority of the NNC method remains unchanged. The application of the proposed model across different industries represents a significant research direction for future research. | ||
کلیدواژهها | ||
Supply chain network design (SCND)؛ Sustainability؛ Reliability؛ Augmented ε-constraint (AEC)؛ Normalized normal constraint (NNC) | ||
مراجع | ||
[1] Abir, A.S., Bhuiyan, I. A., Arani, M., Billal, M.M. (2020). “Multi-objective optimization for sustainable closed-loop supply chain network under demand uncertainty: A genetic algorithm”, In 2020 International Conference on Data Analytics for Business and Industry: Way Towards a Sustainable Economy (ICDABI) (pp. 1-5). IEEE.
[2] Ahi, P., Searcy, C. (2015). “An analysis of metrics used to measure performance in green and sustainable supply chains”, Journal of Cleaner Production, 86, 360-377.
[3] Ahmadigorji, M., Amjady, N., Dehghan, S. (2017). “A robust model for multiyear distribution network reinforcement planning based on information-gap decision theory”, IEEE Transactions on Power Systems, 33(2), 1339-1351.
[4] Akbari-Kasgari, M., Khademi-Zare, H., Fakhrzad, M.B., Hajiaghaei-Keshteli, M., Honarvar, M. (2022). “Designing a resilient and sustainable closed-loop supply chain network in copper industry”, Clean Technologies and Environmental Policy, 1-28.
[5] Amirian, S., Amiri, M., Taghavifard, M.T. (2022a). “The Emergence of a Sustainable and Reliable Supply Chain Paradigm in Supply Chain Network Design”, Complexity, 2022.
[6] Amirian, S., Amiri, M., Taghavifard, M.T. (2022b). “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.
[7] Basu, D., Lee, M. (2022). “A combined sustainability-reliability approach in geotechnical engineering”, In Risk, Reliability and Sustainable Remediation in the Field of Civil and Environmental Engineering (pp. 379-413). Elsevier.
[8] Bektaş, T., Laporte, G. (2011). “The pollution-routing problem”, Transportation Research Part B: Methodological, 45(8), 1232-1250.
[9] Boronoos, M., Mousazadeh, M., Torabi, S.A. (2021). “A robust mixed flexible-possibilistic programming approach for multi-objective closed-loop green supply chain network design”, Environment, Development and Sustainability, 23(3), 3368-3395.
[10] Chambari, A., Rahmati, S.H.A., Najafi, A.A. (2012). “A bi-objective model to optimize reliability and cost of system with a choice of redundancy strategies”, Computers & Industrial Engineering, 63(1), 109-119.
[11] Dullaert, W., Zamparini, L. (2013). “The impact of lead time reliability in freight transport: A logistics assessment of transport economics findings”, Transportation Research Part E: Logistics and Transportation Review, 49(1), 190-200.
[12] Eslamipoor, R., Nobari, A. (2023). “A reliable and sustainable design of supply chain in healthcare under uncertainty regarding environmental impacts”, Journal of Applied Research on Industrial Engineering, 10(2), 256-272.
[13] Fakhrzad, M.B., Goodarzian, F. (2019). “A fuzzy multi-objective programming approach to develop a green closed-loop supply chain network design problem under uncertainty: modifications of imperialist competitive algorithm”, RAIRO-Operations Research, 53(3), 963-990.
[14] Fattahi, M., Govindan, K. (2018). “A multi-stage stochastic program for the sustainable design of biofuel supply chain networks under biomass supply uncertainty and disruption risk: A real-life case study”, Transportation Research Part E: Logistics and Transportation Review, 118, 534-567
[15] Fazli-Khalaf, M., Mirzazadeh, A., Pishvaee, M.S.(2017).“A robust fuzzy stochastic programming model for the design of a reliable green closed-loop supply chain network”, Human and Ecological Risk Assessment: an International Journal, 23(8), 2119-2149.
[16] Fazli-Khalaf, M., Naderi, B., Mohammadi, M., Pishvaee, M.S. (2020).“Design of a sustainable and reliable hydrogen supply chain network under mixed uncertainties: A case study”, International Journal of Hydrogen Energy, 45(59), 34503-34531.
[17] Fazli-Khalaf, M., Naderi, B., Mohammadi, M., Pishvaee, M.S. (2021). “The design of a resilient and sustainable maximal covering closed-loop supply chain network under hybrid uncertainties: A case study in tire industry”, Environment, Development and Sustainability, 23(7), 9949-9973.
[18] Foong, S.Z., Ng, D.K. (2022).“ A systematic approach for synthesis and optimisation of sustainable oil palm value chain (OPVC)”, South African Journal of Chemical Engineering, 41, 65-78.
[19] Ghayebloo, S., Tarokh, M.J., Venkatadri, U., Diallo, C. (2015). “Developing a bi-objective model of the closed-loop supply chain network with green supplier selection and disassembly of products: The impact of parts reliability and product greenness on the recovery network”, Journal of Manufacturing Systems, 36, 76-86.
[20] Ghobakhloo, M., Iranmanesh, M., Mubarak, M.F., Mubarik, M., Rejeb, A., Nilashi, M. (2022). “Identifying industry 5.0 contributions to sustainable development: A strategy roadmap for delivering sustainability values”, Sustainable Production and Consumption, 33, 716-737.
[21] Gong, D.C., Chen, P.S., Lu, T.Y. (2017). “Multi-objective optimization of green supply chain network designs for transportation mode selection”, Scientia Iranica, 24(6), 3355-3370.
[22] Govindan, K., Gholizadeh, H. (2021). “Robust network design for sustainable-resilient reverse logistics network using big data: A case study of end-of-life vehicles”, Transportation Research Part E: Logistics and Transportation Review, 149, 102279.
[23] Govindan, K., Fattahi, M., Keyvanshokooh, E. (2017). “Supply chain network design under uncertainty: A comprehensive review and future research directions”, European Journal of Operational
Research, 263(1), 108-141.
[24] Hamidieh, A., Naderi, B., Mohammadi, M., Fazli-Khalaf, M. (2017). “A robust possibilistic programming model for a responsive closed loop supply chain network design”, Cogent Mathematics, 4(1), 1329886.
[25] Hosseini-Motlagh, S.M., Samani, M.R.G., Shahbazbegian, V. (2020). “Innovative strategy to design a mixed resilient-sustainable electricity supply chain network under uncertainty”, Applied Energy, 280, 115921.
[26] Ivanov, D., Das, A. (2020). “Coronavirus (COVID-19/SARS-CoV-2) and supply chain resilience: A research note”, International Journal of Integrated Supply Management, 13(1), 90-102.
[27] Jabbarzadeh, A., Fahimnia, B., Sabouhi, F. (2018). “Resilient and sustainable supply chain design: Sustainability analysis under disruption risks”, International Journal of Production Research, 56(17), 5945-5968.
[28] Kabadurmus, O., Erdogan, M.S. (2020). “Sustainable, multimodal and reliable supply chain design”, Annals of Operations Research, 292(1), 47-70.
[29] Kaur, H., Singh, S.P. (2019). “Sustainable procurement and logistics for disaster resilient supply chain”, Annals of Operations Research, 283(1), 309-354.
[30] Khosravi, K., Pourghasemi, H.R., Chapi, K., Bahri, M. (2016). “Flash flood susceptibility analysis and its mapping using different bivariate models in Iran: A comparison between Shannon’s entropy, statistical index, and weighting factor models”, Environmental Monitoring and Assessment, 188(12), 1-21.
[31] Li, Q., Loy-Benitez, J., Nam, K., Hwangbo, S., Rashidi, J., Yoo, C. (2019). “Sustainable and reliable design of reverse osmosis desalination with hybrid renewable energy systems through supply chain forecasting using recurrent neural networks”, Energy, 178, 277-292.
[32] Liu, J., Feng, Y., Zhu, Q., Sarkis, J. (2018). “Green supply chain management and the circular economy: Reviewing theory for advancement of both fields”, International Journal of Physical Distribution & Logistics Management, 48(8), 794 - 817.
[33] Marchi, B., Zanoni, S., Zavanella, L.E., Jaber, M.Y. (2019). “Supply chain models with greenhouse gases emissions, energy usage, imperfect process under different coordination decisions”, International Journal of Production Economics, 211, 145-153.
[34] Mavrotas, G. (2009). “Effective implementation of the ε-constraint method in multi-objective mathematical programming problems”, Applied Mathematics and Computation, 213(2), 455-465.
[35] Mavrotas, G., Florios, K. (2013). “An improved version of the augmented ε-constraint method (AUGMECON2) for finding the exact Pareto set in multi-objective integer programming problems”, Applied Mathematics and Computation, 219(18), 9652-9669.
[36] Messac, A., Mattson, C.A. (2004). “Normal constraint method with guarantee of even representation of complete Pareto frontier”, AIAA Journal, 42(10), 2101-2111.
[37] Mirzapour Al-e-hashem, S.M.J., Rekik, Y. (2014). “Multi-product multi-period inventory routing problem with a transshipment option: A green approach”, International Journal of Production Economics, 157, 80-88.
[38] Mousavi Ahranjani, P., Ghaderi, S.F., Azadeh, A., Babazadeh, R. (2020). “Robust design of a sustainable and resilient bioethanol supply chain under operational and disruption risks”, Clean Technologies and Environmental Policy, 22(1), 119-151.
[39] Nosrati, M., Khamseh, A. (2020). “Reliability optimization in a four-echelon green closed-loop supply chain network considering stochastic demand and carbon price”, Uncertain Supply Chain Management, 8(3), 457-472.
[40] Pereira, J.L.J., Oliver, G.A., Francisco, M.B., Cunha, S.S., Gomes, G.F. (2021).“A review of multi-objective optimization: methods and algorithms in mechanical engineering problems”, Archives of Computational Methods in Engineering, 1-24.
[41] Rahmani, S., Amjady, N. (2018). “Improved normalized normal constraint method to solve multi-objective optimal power flow problem”, IET Generation, Transmission & Distribution, 12(4), 859-872.
[42] Rahmani, D., Mahoodian, V. (2017). “Strategic and operational supply chain network design to reduce carbon emission considering reliability and robustness”, Journal of Cleaner Production, 149, 607-620.
[43] Rohaninejad, M., Sahraeian, R., Tavakkoli-Moghaddam, R. (2018). “Multi-echelon supply chain design considering unreliable facilities with facility hardening possibility”, Applied Mathematical Modelling, 62, 321-337.
[44] Salehi, M., Jabarpour, E.(2020).“Modeling and solving a multi-objective location-routing problem considering the evacuation of casualties and homeless people and fuzzy paths in relief logistics”, Control and Optimization in Applied Mathematics, 5(1), 41-65.
[45] Sundarakani, B., De Souza, R., Goh, M., Wagner, S.M., Manikandan, S. (2010). “Modeling carbon footprints across the supply chain”, International Journal of Production Economics, 128(1), 43-50.
[46] Tao, J., Shao, L., Guan, Z., Ho, W., Talluri, S. (2020). “Incorporating risk aversion and fairness considerations into procurement and distribution decisions in a supply chain”, International Journal of Production Research, 58(7), 1950-1967.
[47] Tirkolaee, E.B., Mardani, A., Dashtian, Z., Soltani, M., Weber, G.W. (2020). “A novel hybrid method using fuzzy decision making and multi-objective programming for sustainable-reliable supplier selection in two-echelon supply chain design”, Journal of Cleaner Production, 250, 119517.
[48] Torjai, L., Nagy, J., Bai, A. (2015). “Decision hierarchy, competitive priorities and indicators in large-scale ‘herbaceous biomass to energy supply chains”, Biomass and Bioenergy, 80, 321-329.
[49] Wang, F., Lai, X., Shi, N. (2011). “A multi-objective optimization for green supply chain network design”, Decision Support Systems, 51(2), 262-269.
[50] Wang, B., Zhang, H., Yuan, M., Guo, Z., Liang, Y. (2020). “Sustainable refined products supply chain: a reliability assessment for demand side management in primary distribution processes”, Energy Science & Engineering, 8(4), 1029-1049.
[51] Yılmaz, Ö.F., Özçelik, G., Yeni, F.B. (2021). “Ensuring sustainability in the reverse supply chain in case of the ripple effect: A two-stage stochastic optimization model”, Journal of Cleaner Production, 282, 124548.
[52] Zahiri, B., Zhuang, J., Mohammadi, M. (2017). “Toward an integrated sustainable-resilient supply chain: A pharmaceutical case study”, Transportation Research Part E: Logistics and Transportation Review, 103, 109-142.
[53] Zitzler, E., Thiele, L. (1998). “Multi-objective optimization using evolutionary algorithms—a comparative case study”, In International Conference on Parallel Problem Solving from Nature (pp. 292- 301). Springer, Berlin, Heidelberg. | ||
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