no. 6
A bi-objective integrated transportation and inventory management under a supply chain network considering multiple distribution networks
RAIRO. Operations Research, Tome 56 (2022) no. 6, pp. 3991-4022

In order to respond to the customer’s needs effectively and efficiently, logistics is characterized as a part of the supply chain that executes and handles forward and reverse movement and storage of products, services, and related data. An efficient logistic network is needed for the supply chain that executes forward and reverses products’ movement. This study resolves the supply chain network’s logistic problem to determine the appropriate order allocation of products from multiple plants, warehouses, and distributors to minimize total transportation and inventory costs by simultaneously determining optimal locations, flows, shipment composition, and shipment cycle times. The multi-objective logistic cost minimizes through the value function approach for obtaining the optimal order allocation. An actual data-based case study has been applied to examine the effectiveness of the multi-objective supply chain network. These results are very relevant for the manufacturing sectors, particularly those facing the logistics issue in the supply chain network. The findings indicate the optimal logistic costs. The results enable managers to cope with various types of logistics risks.

Reçu le :
Accepté le :
Première publication :
Publié le :
DOI : 10.1051/ro/2022164
Classification : 90B06, 90C39
Keywords: Multi-level networking, multi-objective optimization, supply chain network, logistic management, value function approach 
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Gupta, Srikant; Vijaygargy, Lokesh; Sarkar, Biswajit. A bi-objective integrated transportation and inventory management under a supply chain network considering multiple distribution networks. RAIRO. Operations Research, Tome 56 (2022) no. 6, pp. 3991-4022. doi: 10.1051/ro/2022164

[1] G. Ahmadi, S. A. Torabi and R. Tavakkoli-Moghaddam, A bi-objective location-inventory model with capacitated transportation and lateral transshipments. Int. J. Prod. Res. 54 (2016) 2035–2056.

[2] M. Akbarpour, S. A. Torabi and A. Ghavamifar, Designing an integrated pharmaceutical relief chain network under demand uncertainty. Transp. Res. Part E Logist. Transp. Rev. 136 (2020) 101867.

[3] I. Ali, S. Gupta and A. Ahmed, Multi-objective linear fractional inventory problem under intuitionistic fuzzy environment. Int. J. Syst. Assur. Eng. Manag. 10 (2019) 173–189.

[4] E. M. Alvarez, M. C. Van Der Heiden, I. M. H. Vliegen and W. H. M. Zijm, Service differentiation through selective lateral transshipments. Eur. J. Oper. Res. 237 (2014) 824–835.

[5] S. H. Amin and F. Baki, A facility location model for global closed-loop supply chain network design. App. Math. Model. 41 (2017) 316–330.

[6] A. Arasteh, Supply chain management under uncertainty with the combination of fuzzy multi-objective planning and real options approaches. Soft Comput. 24 (2021) 5177–5198.

[7] M. G. Avci and H. Selim, A multi-objective simulation-based optimization approach for inventory replenishment problem with premium freights in convergent supply chains. Omega 80 (2018) 153–165.

[8] S. Bandyopadhyay and R. Bhattacharya, Solving a tri-objective supply chain problem with modified NSGA-II algorithm. J. Manuf. Syst. 33 (2014) 41–50.

[9] M. Bashiri, H. Badri and J. Talebi, A new approach to tactical and strategic planning in production–distribution networks. App. Math. Model. 36 (2012) 1703–1717.

[10] A. K. Bera, D. K. Jana, D. Banerjee and T. Nandy, A two-phase multi-criteria fuzzy group decision making approach for supplier evaluation and order allocation considering multi-objective, multi-product and multi-period. Ann. Data Sci. 8 (2020) 577–601.

[11] B. Bilgen, Application of fuzzy mathematical programming approach to the production allocation and distribution supply chain network problem. Expert Syst. App. 37 (2010) 4488–4495.

[12] C. Bilir, S. O. Ekici and F. Ulengin, An integrated multi-objective supply chain network and competitive facility location model, Comput. Ind. Eng. 108 (2017) 136–148.

[13] H. L. Chan, X. Wei, S. Guo and W. H. Leung, Corporate social responsibility (CSR) in fashion supply chains: a multi-methodological study. Transp. Res. Part E Logist. Transp. Rev. 142 (2020) 102063.

[14] V. Charles, S. Gupta and I. Ali, A fuzzy goal programming approach for solving multi-objective supply chain network problems with pareto-distributed random variables. Int. J. Uncertainty Fuzziness Knowlege Based Syst. 27 (2019) 559–593.

[15] S. B. Choi, B. K. Dey, S. J. Kim and B. Sarkar, Intelligent servicing strategy for an online-to-offline (O2O) supply chain under demand variability and controllable lead time. RAIRO: Oper. Res. 56 (2022) 1623–1653.

[16] F. Delfani, H. Samanipour, H. Beiki, A. V. Yumashev and E. M. Akhmetshin, A robust fuzzy optimisation for a multi-objective pharmaceutical supply chain network design problem considering reliability and delivery time. Int. J. Syst. Sci. Oper. Logist. 9 (2020) 155–179.

[17] M. Daz-Madroñero, D. Peidro and J. Mula, A fuzzy optimization approach for procurement transport operational planning in an automobile supply chain. App. Math. Model. 38 (2014) 5705–5725.

[18] H. Ensafian and S. Yaghoubi, Robust optimization model for integrated procurement, production and distribution in platelet supply chain. Transp. Res. Part E Logist. Transp. Rev. 103 (2017) 32–55.

[19] M. Fattahi, K. Govindan and E. Keyvanshokooh, A multi-stage stochastic program for supply chain network redesign problem with price-dependent uncertain demands. Comput. Operat. Res. 100 (2018) 314–332.

[20] A. Garai and B. Sarkar, Economically independent reverse logistics of customer-centric closed-loop supply chain for herbal medicines and biofuel. J. Clean. Prod. 334 (2022) 129977.

[21] B. Gaudenzi and M. Christopher, Achieving supply chain “Leagility” through a project management orientation. Int. J. Logist. Res. App. 19 (2016) 3–18.

[22] A. L. Guiffrida and M. Y. Jaber, Managerial and economic impacts of reducing delivery variance in the supply chain. App. Math. Model. 32 (2008) 2149–2161.

[23] S. Gupta, I. Ali and A. Ahmed, Efficient fuzzy goal programming model for multi-objective production distribution problem. Int. J. App. Comput. Math. 4 (2018) 76.

[24] S. Gupta, H. Garg and S. Chaudhary, Parameter estimation and optimization of multi-objective capacitated stochastic transportation problem for gamma distribution. Complex Intell. Syst. 6 (2020) 651–667.

[25] S. Gupta, S. Chaudhary, P. Chatterjee and M. Yazdani, An efficient stochastic programming approach for solving integrated multi-objective transportation and inventory management problem using goodness of fit. Kybernetes 51 (2021) 768–803.

[26] D. Han, Y. Yang, D. Wang, T. C. E. Cheng and Y. Yin, Integrated production, inventory, and outbound distribution operations with fixed departure times in a three-stage supply chain. Transp. Res. Part E Logist. Transp. Rev. 125 (2019) 334–347.

[27] M. Kadziński, T. Tervonen, M. K. Tomczyk and R. Dekker, Evaluation of multi-objective optimization approaches for solving green supply chain design problems. Omega 68 (2017) 168–184.

[28] A. S. H. Kugele, W. Ahmed and B. Sarkar, Geometric programming solution of second degree difficulty for carbon ejection controlled reliable smart production system. RAIRO: OR 56 (2022) 1013–1029.

[29] S. Kumar, M. Sigroha, K. Kumar and B. Sarkar, Manufacturing/remanufacturing based supply chain management under advertisements and carbon emission process. RAIRO: OR 56 (2022) 831–851.

[30] T. F. Liang, Fuzzy multi-objective production/distribution planning decisions with multi-product and multi-time period in a supply chain. Comput. Ind. Eng. 55 (2008) 676–694.

[31] S. Liu, L. G. Papageorgiou, Multi-objective optimization of production, distribution and capacity planning of global supply chains in the process industry. Omega 41 (2013) 369–382.

[32] A. S. Mahapatra, M. S. Mahapatra, B. Sarkar and S. K. Majumder, Benefit of preservation technology with promotion and time-dependent deterioration under fuzzy learning. Expert. Syst. App. 201 (2022) 117169.

[33] M. Mahmoodi, A new multi-objective model of agile supply chain network design considering transportation limits. Prod. Manuf. Res. 7 (2019) 1–22.

[34] J. T. Margolis, K. M. Sullivan, S. J. Mason and M. Magagnotti, A multi-objective optimization model for designing resilient supply chain networks. Int. J. Prod. Econ. 204 (2018) 174–185.

[35] S. Min, Z. G. Zacharia and C. D. Smith, Defining supply chain management: in the past, present, and future. J. Bus. Logist. 40 (2019) 44–55.

[36] A. M. Mohammed and S. O. Duffuaa, A tabu search based algorithm for the optimal design of multi-objective multi-product supply chain networks. Expert. Syst. App. 140 (2020) 112808.

[37] I. Moon, W. Y. Yun and B. Sarkar, Effects of variable setup cost, reliability, and production costs under controlled carbon emissions in a reliable production system. Eur. J. Ind. Eng. 16 (2022) 371–397.

[38] K. P. Nurjanni, M. S. Carvalho and L. Costa, Green supply chain design: a mathematical modeling approach based on a multi-objective optimization model. Int. J. Prod. Econ. 183 (2017) 421–432.

[39] D. Peidro, J. Mula, M. M. E. Alemany and F. C. Lario, Fuzzy multi-objective optimisation for master planning in a ceramic supply chain. Int. J. Prod. Res. 50 (2012) 3011–3020.

[40] E. H. Sabri and B. M. Beamon, A multi-objective approach to simultaneous strategic and operational planning in supply chain design. Omega 28 (2000) 581–598.

[41] J. Sadeghi, S. M. Mousavi, S. T. A. Niaki and S. Sadeghi, Optimizing a bi-objective inventory model of a three-echelon supply chain using a tuned hybrid bat algorithm. Transp. Res. Part E Logist. Transp. Rev. 70 (2014) 274–292.

[42] A. N. Sadigh, H. Fallah and N. Nahavandi, A multi-objective supply chain model integrated with location of distribution centers and supplier selection decisions. Int. J. Adv. Manuf. Tech. 69 (2013) 225–235.

[43] B. Sarkar and S. Bhuniya, A sustainable flexible manufacturing–remanufacturing model with improved service and green investment under variable demand. Expert. Syst. App. 202 (2022) 117154.

[44] A. Sarkar, R. Guchhait and B. Sarkar, Application of the artificial neural network with multithreading within an inventory model under uncertainty and inflation. Int. J. Fuzzy Syst. 24 (2022) 2318–2332.

[45] B. Sarkar, J. Joo, Y. Kim, H. Park and M. Sarkar, Controlling defective items in a complex multi-phase manufacturing system. RAIRO: OR 56 (2022) 871–889.

[46] B. Sarkar, M. Ullah and M. Sarkar, Environmental and economic sustainability through innovative green products by remanufacturing. J. Clean. Prod. 332 (2022) 129813.

[47] K. Sarrafha, S. H. A. Rahmati, S. T. A. Niaki and A. Zaretalab, A bi-objective integrated procurement, production, and distribution problem of a multi-echelon supply chain network design: a new tuned MOEA. Comput. Oper. Res. 54 (2015) 35–51.

[48] A. Seidscher and S. Minner, A Semi-Markov decision problem for proactive and reactive transshipments between multiple warehouses. Eur. J. Oper. Res. 230 (2013) 42–52.

[49] S. K. Singh and M. Goh, Multi-objective mixed integer programming and an application in a pharmaceutical supply chain. Int. J. Prod. Res. 57 (2019) 1214–1237.

[50] F. J. Tapia-Ubeda, P. A. Miranda, I. Roda, M. Macchi and O. Durán, Modelling and solving spare parts supply chain network design problems. Int. J. Prod. Res. 58 (2020) 5299–5319.

[51] S. A. Torabi, E. Hassini and M. Jeihoonian, Fulfillment source allocation, inventory transshipment, and customer order transfer in e-tailing. Transp. Res. Part E Logist. Transp. Rev. 79 (2015) 128–144.

[52] S. C. Tsai and S. T. Chen, A simulation-based multi-objective optimization framework: a case study on inventory management. Omega 70 (2017) 148–159.

[53] U. R. Tuzkaya and S. Önüt, A holonic approach based integration methodology for transportation and warehousing functions of the supply network. Comput. Indust. Eng. 56 (2009) 708–723.

[54] S. Validi, A. Bhattacharya and P. J. Byrne, A case analysis of a sustainable food supply chain distribution system – A multi-objective approach. Int. J. Prod. Econ. 152 (2014) 71–87.

[55] K. J. Wang, B. Makond and S. Y. Liu, Location and allocation decisions in a two-echelon supply chain with stochastic demand – A genetic-algorithm based solution. Expert. Syst. App. 8 (2011) 6125–6131.

[56] J. Xu, Q. Liu and R. Wang, A class of multi-objective supply chain networks optimal model under random fuzzy environment and its application to the industry of Chinese liquor. Inf. Sci. 178 (2008) 2022–2043.

[57] D. Yadav, R. Singh, A. Kumar and B. Sarkar, Reduction of pollution through sustainable and flexible production by controlling by-products. J. Environ. Inform. 40 (2022) 106–124.

[58] S. Zandkarimkhani, H. Mina, M. Biuki and K. Govindan, A chance constrained fuzzy goal programming approach for perishable pharmaceutical supply chain network design. Ann. Oper. Res. 295 (2020) 425–452.

[59] S. Zhang, C. K. M. Lee, K. Wu and K. L. Choy, Multi-objective optimization for sustainable supply chain network design considering multiple distribution channels. Expert. Syst. App. 65 (2016) 87–99.

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