Journal of Quality Engineering and Management

Proposing a data-driven decision-making model for evaluating sustainable and resilient suppliers in the automotive industry

Document Type : Original Article

Authors

Seyedeh Mahboubeh Saeidifar
Iraj Mahdavi
Ali Tajdin
Nikbakhsh Javadian

Department of Industrial Engineering, Mazandaran University of Science and Technology, Babol, Iran.

https://doi.org/10.48313/jqem.2025.529590.1555
Abstract
Purpose: In light of the growing challenges in today's supply chains, including market fluctuations, increasing environmental and social pressures, and the need to enhance resilience against foreseeable crises such as the COVID-19 pandemic and economic disruptions, the strategic importance of selecting suppliers that simultaneously meet sustainability and resilience criteria has become more prominent. Accordingly, the main objective of this study is to present a comprehensive, data-driven, and forward-looking decision-making model for evaluating and selecting suppliers within the supply chain, accounting for multiple dimensions of sustainability and resilience simultaneously.
Methodology: In the proposed model, the weights of the defined criteria and sub-criteria were initially determined using the Stochastic Best-Worst Method (SBWM). Supplier performance was then evaluated using the Stochastic VIKOR Multi-Criteria Decision-Making (MCDM) method. In the final stage, the Random Forest regression algorithm was applied to predict future supplier performance. The model was tested through a case study conducted at SAIPA Kashan Automotive Company using expert input collected via structured questionnaires.
Findings: Sustainability and resilience criteria play a central role in supplier selection in the automotive industry. Among the sub-criteria, "greenhouse gas emissions" and "energy consumption reduction" were most influential due to environmental regulations. At the same time, "cost" and "safety stock level" had the greatest impact due to their direct effect on economic performance and operational continuity. Furthermore, the Random Forest algorithm achieved high predictive accuracy (RMSE = 0.0976), confirming the model's ability to generate reliable, data-driven forecasts.
Originality/Value: Although each of the methods used in this research (Random Best-Worst Method, Random VIKOR, and Random Forest algorithm) has been employed individually in previous studies, the main innovation of this study lies in presenting an integrated framework that combines all three approaches. In fact, this research is the first to merge MCDM methods with a machine learning algorithm, offering a comprehensive, data-driven decision-making model. This model not only assesses the current performance of suppliers but also enables prediction of their future performance. Such a combination has not previously been introduced in the supplier selection literature with a simultaneous focus on supply chain sustainability and resilience in the automotive industry, marking a clear methodological innovation.

Keywords

Supplier selection
Sustainability
Resiliency
Automotive industry
Random Forest algorithm
[1]     Azaron, A., Venkatadri, U., & Doost, A. F. (2019). Designing profitable and responsive supply chains under uncertainty. IFAC-papersonline, 52(13), 2816–2820. https://doi.org/10.1016/j.ifacol.2019.11.635
[2]     Subramanian, B., Mishra, A., Ramkumar, B. V., Mandala, G., Kathamuthu, N. D., & Srithar, S. (2025). Big data and fuzzy logic for demand forecasting in supply chain management: A data-driven approach. Journal of fuzzy extension and applications, 6(2), 260–283. https://doi.org/10.22105/jfea.2025.488816.1703
[3]     Elbaz, J., & Iddik, S. (2020). Culture and green supply chain management (GSCM) A systematic literature review and a proposal of a model. Management of environmental quality: An international journal, 31(2), 483–504. https://doi.org/10.1108/MEQ-09-2019-0197
[4]     Fattahi, M., Govindan, K., & Keyvanshokooh, E. (2017). Responsive and resilient supply chain network design under operational and disruption risks with delivery lead-time sensitive customers. Transportation research part E: Logistics and transportation review, 101, 176–200. https://doi.org/10.1016/j.tre.2017.02.004
[5]     Asadi, Z., Aghajani, H., Valipourkhatir, M., & Babaee Tirkolaee, E. (2024). A hybrid fuzzy decision-making approach for evaluating the suppliers based on industry 5.0 and viable supply chain dimensions: A case study in medical devices manufacturing. Journal of decisions and operations research, 9(2), 399-418. (In Persian). https://doi.org/10.22105/dmor.2023.408308.1773
[6]     Bayatzadeh, S., & Talaie, H. (2024). Identifying and evaluating of sustainable and resilient supplier selection criteria according to industry 5.0 concepts (Case study: Steel industry). Journal of decisions and operations research, 9(4), 1045-1063. (In Persian). https://doi.org/10.22105/dmor.2025.498734.1904
[7]     Hesami, F. (2024). A hybrid ANP-TOPSIS method for strategic supplier selection in RL under rough uncertainty: A case study in the electronics industry. Uncertainty discourse and applications, 1(1), 41–65. (In Persian). https://doi.org/10.22105/dmor.2025.498734.1904
[8]     Tushar, Z. N., Bari, A. B. M. M., & Khan, M. A. (2022). Circular supplier selection in the construction industry: A sustainability perspective for the emerging economies. Sustainable manufacturing and service economics, 1, 100005. https://doi.org/10.22105/dmor.2025.498734.1904
[9]     Nayeri, S., Sazvar, Z., & Heydari, J. (2022). A global-responsive supply chain considering sustainability and resiliency: Application in the medical devices industry. Socio-economic planning sciences. https://doi.org/10.1016/j.seps.2022.101303
[10]   Hoseini, S. A., Fallahpour, A., Wong, K. Y., Mahdiyar, A., Saberi, M., & Durdyev, S. (2021). Sustainable supplier selection in construction industry through hybrid fuzzy-based approaches. Sustainability, 13(3), 1413. https://doi.org/10.3390/su13031413
[11]   Fallahiarezoudar, E., Alami, F., & Ahmadipourroudposht, M. (2022). Developing a multi-objective mathematical model of green closed-loop supply chain In terms of selling returned products using the Epsilon-constraint method approach. Journal of quality engineering and management, 11(4), 351-376. (In Persian). https://dor.isc.ac/dor/20.1001.1.23221305.1400.11.4.3.2
[12]   Silva, A. C., Marques, C. M., & Sousa, J. P. De. (2023). A simulation approach for the design of more sustainable and resilient supply chains in the pharmaceutical industry. Sustainability, 15(9), 7254. https://doi.org/10.3390/su15097254
[13]   Echefaj, K., Charkaoui, A., Cherrafi, A., Garza-Reyes, J. A., Khan, S. A. R., & Chaouni Benabdellah, A. (2023). Sustainable and resilient supplier selection in the context of circular economy: An ontology-based model. Management of environmental quality: an international journal, 34(5), 1461–1489. https://doi.org/10.1108/MEQ-02-2023-0037
[14]   Solgi, O., Gheidar-Kheljani, J., Dehghani, E., & Taromi, A. (2021). Resilient supplier selection in complex products and their subsystem supply chains under uncertainty and risk disruption: A case study for satellite components. Scientia iranica, 28(3), 1802–1816. https://doi.org/10.24200/sci.2019.52556.2773
[15]   Hosseini Dehshiri, S. J., & Aghaei, M. (2021). Identifying and ranking technological capabilities to enhance resilience of the supply chain. Innovation management and operational strategies, 2(3), 229-243. (In Persian). https://doi.org/10.22105/imos.2021.288228.1101
[16]   Li, Y. L., Tsang, Y. P., Wu, C. H., & Lee, C. K. M. (2024). A multi-agent digital twin–enabled decision support system for sustainable and resilient supplier management. Computers & industrial engineering, 187, 109838. https://doi.org/10.1016/j.cie.2023.109838
[17]   Hasani, A., & Khosrojerdi, A. (2016). Robust global supply chain network design under disruption and uncertainty considering resilience strategies: A parallel memetic algorithm for a real-life case study. Transportation research part E: Logistics and transportation review, 87, 20–52. https://doi.org/10.1016/j.tre.2015.12.009
[18]   Arji, G., Ahmadi, H., Avazpoor, P., & Hemmat, M. (2023). Identifying resilience strategies for disruption management in the healthcare supply chain during COVID-19 by digital innovations: A systematic literature review. Informatics in medicine unlocked, 38, 101199. https://doi.org/10.1016/j.imu.2023.101199
[19]   Gökler, S. H., & Boran, S. (2025). A novel resilient and sustainable supplier selection model based on D-AHP and DEMATEL methods. Journal of engineering research, 13(1), 57–67. https://doi.org/10.1016/j.jer.2023.07.015
[20]   Rezaei, A., Aghsami, A., & Rabbani, M. (2021). Supplier selection and order allocation model with disruption and environmental risks in centralized supply chain. International journal of system assurance engineering and management, 12(6), 1036–1072.
[21]   Vahidi, F., Torabi, S. A., & Ramezankhani, M. J. (2018). Sustainable supplier selection and order allocation under operational and disruption risks. Journal of cleaner production, 174, 1351–1365. https://doi.org/10.1016/j.jclepro.2017.11.012
[22]   Ivanov, D. (2021). Supply Chain Viability and the COVID-19 pandemic: A conceptual and formal generalisation of four major adaptation strategies. International journal of production research, 59(12), 3535–3552. https://doi.org/10.1080/00207543.2021.1890852
[23]   Tong, L. Z., Wang, J., & Pu, Z. (2022). Sustainable supplier selection for SMEs based on an extended PROMETHEE Ⅱ approach. Journal of cleaner production, 330, 129830. https://doi.org/10.1016/j.jclepro.2021.129830
[24]   Kusi-Sarpong, S., Gupta, H., Khan, S. A., Chiappetta Jabbour, C. J., Rehman, S. T., & Kusi-Sarpong, H. (2023). Sustainable supplier selection based on industry 4.0 initiatives within the context of circular economy implementation in supply chain operations. Production planning and control, 34(10), 999–1019. https://doi.org/10.1080/09537287.2021.1980906
[25]   Nasrollahi, M., Fathi, M. R., Sobhani, S. M., Khosravi, A., & Noorbakhsh, A. (2023). Modeling resilient supplier selection criteria in desalination supply chain based on fuzzy DEMATEL and ISM. In Sustainable logistics systems using ai-based meta-heuristics approaches (pp. 101–115). Routledge. http://dx.doi.org/10.4324/9781032634401-9
[26]   Rezaei, A. R., & Qiong, L. (2024). Robust supply chain network design with resilient supplier selection under disruption risks. Journal of applied research on industrial engineering, 11(3), 398–422. https://doi.org/10.22105/jarie.2023.417363.1564
[27]   Afrasiabi, A., Tavana, M., & Di Caprio, D. (2022). An extended hybrid fuzzy multi-criteria decision model for sustainable and resilient supplier selection. Environmental science and pollution research, 1–24. https://doi.org/10.1007/s11356-021-17851-2
[28]   Ghamari, R., Mahdavi-Mazdeh, M., & Ghannadpour, S. F. (2022). Resilient and sustainable supplier selection via a new framework: A case study from the steel industry. Environment, development and sustainability, 1–39. https://doi.org/10.1007/s10668-021-01872-5
[29]   Nayeri, S., Khoei, M. A., Rouhani-Tazangi, M. R., GhanavatiNejad, M., Rahmani, M., & Tirkolaee, E. B. (2023). A data-driven model for sustainable and resilient supplier selection and order allocation problem in a responsive supply chain: A case study of healthcare system. Engineering applications of artificial intelligence, 124, 106511. https://doi.org/10.1016/j.engappai.2023.106511
[30]   Rahnamay Bonab, S., Haseli, G., Rajabzadeh, H., Ghoushchi, S., Hajiaghaei-Keshteli, M., & Tomášková, H. (2023). Sustainable resilient supplier selection for IoT implementation based on the integrated BWM and TRUST under Spherical fuzzy sets. Decision making: Applications in management and engineering, 6(1), 153–185. http://dx.doi.org/10.31181/dmame12012023b
[31]   Sheykhizadeh, M., Ghasemi, R., Vandchali, H. R., Sepehri, A., & Torabi, S. A. (2024). A hybrid decision-making framework for a supplier selection problem based on lean, agile, resilience, and green criteria: A case study of a pharmaceutical industry. Environment, development and sustainability, 26(12), 30969–30996. https://doi.org/10.1007/s10668-023-04135-7
[32]   Varchandi, S., Memari, A., & Jokar, M. R. A. (2024). An integrated best–worst method and fuzzy TOPSIS for resilient-sustainable supplier selection. Decision analytics journal, 11, 100488. https://doi.org/10.1016/j.dajour.2024.100488
[33]   Becerra, P., & Diaz, J. (2025). Supplier selection model considering sustainable and resilience aspects for mining industry. Systems, 13(2), 81. https://doi.org/10.3390/systems13020081
[34]   Laily, A. R. N., & Masruroh, N. A. (2025). Supplier selection model considering resilience and sustainability aspects. AIP conference proceedings. AIP Publishing. https://doi.org/10.1063/5.0231054
[35]   Tajally, A., Babakhani, B., Jeyzanibrahimzade, E., Parvin, M., & Irani, S. (2025). Sustainable supplier selection and order allocation problem considering the agility and resilience dimensions: A novel multi-stage data-driven decision-making approach. International journal of systems science: Operations & logistics, 12(1), 2458756. https://doi.org/10.1080/23302674.2025.2458756
[36]   Tajally, A., Vamarzani, M. Z., Ghanavati-Nejad, M., Zeynali, F. R., Abbasian, M., & Bahengam, A. (2025). A hybrid machine learning-based decision-making model for viable supplier selection problem considering circular economy dimensions. Environment, development and sustainability, 1–33. https://doi.org/10.1007/s10668-025-06014-9
[37]   Nayeri, S., Sazvar, Z., & Heydari, J. (2023). Towards a responsive supply chain based on the industry 5.0 dimensions: A novel decision-making method. Expert systems with applications, 213, 119267. https://doi.org/10.1016/j.eswa.2022.119267
[38]   Rezaei, J. (2015). Best-worst multi-criteria decision-making method. Omega, 53, 49–57. https://doi.org/10.1016/j.omega.2014.11.009
[39]   Hosseini, Z. S., Flapper, S. D., & Pirayesh, M. (2022). Sustainable supplier selection and order allocation under demand, supplier availability and supplier grading uncertainties. Computers and industrial engineering, 165, 107811. https://doi.org/10.1016/j.cie.2021.107811
[40]   Parsa Rad, A., Khalilzadeh, M., Banihashemi, S. A., Božanić, D., Milić, A., & Ćirović, G. (2024). Supplier selection in downstream oil and gas and petrochemicals with the Fuzzy BWM and gray COCOSO methods considering sustainability criteria and uncertainty conditions. Sustainability, 16(2), 880. https://doi.org/10.3390/su16020880
[41]   Amiri, M., Hashemi-Tabatabaei, M., Ghahremanloo, M., Keshavarz-Ghorabaee, M., Zavadskas, E. K., & Banaitis, A. (2021). A new fuzzy BWM approach for evaluating and selecting a sustainable supplier in supply chain management. International journal of sustainable development & world ecology, 28(2), 125–142. DOI:10.1080/13504509.2020.1793424
[42]   Noruzi, M., Naderan, A., Zakeri, J. A., & Rahimov, K. (2023). A novel decision-making framework to evaluate rail transport development projects considering sustainability under uncertainty. Sustainability, 15(17), 13086. https://doi.org/10.3390/su151713086
[43]   Liu, Y., Wang, Y., & Zhang, J. (2012). New machine learning algorithm: random forest. International conference on information computing and applications (pp. 246–252). Springer. https://doi.org/10.1007/978-3-642-34062-8_32
[44]   Wilson, V. H., NS, A. P., Shankharan, A., Kapoor, S., & Rajan, J. (2020). Ranking of supplier performance using machine learning algorithm of random forest. International journal of advanced research in engineering and technology (IJARET), 11(5), 298–308. https://doi.org/10.34218/IJARET.11.5.2020.031
[45]   Advitha, G., Varaprasad, A. N., Khushi, K. V., Vijay, P., & Nayak, S. (2024). Cultivating clean skies: Unveiling the tapestry of air quality in Gujarat through innovative machine learning analysis. Big data and computing visions, 4(4), 326–339. https://doi.org/10.22105/bdcv.2024.485515.1213
[46]   Yunxia, G. (2017). Application research of supplier evaluation based on random forest [presentation]. Proceedings of the 6th international conference on software and computer applications (pp. 316–323). http://dx.doi.org/10.1145/3056662.3056718
[47]   Kıran, M., Eşme, E., Torğul, B., & Paksoy, T. (2020). Supplier selection with machine learning algorithms. In Logistics 4.0 (pp. 103–125). CRC Press. https://doi.org/10.1201/9780429327636-11
[48]   Lahtinen, J. (2021). Clustering and classification of material suppliers using machine learning algorithms. https://urn.fi/URN:NBN:fi-fe2021050328621
[49]   Chaouni Benabdellah, A., Zekhnini, K., Cherrafi, A., Garza-Reyes, J. A., Kumar, A., & El Baz, J. (2023). Blockchain technology for viable circular digital supplychains: an integrated approach for evaluating the implementation barriers. Benchmarking: An international journal, 30(10), 4397–4424. https://doi.org/10.1108/BIJ-04-2022-0240
[50]   Eskandari-Khanghahi, M., Tavakkoli-Moghaddam, R., Taleizadeh, A. A., & Amin, S. H. (2018). Designing and optimizing a sustainable supply chain network for a blood platelet bank under uncertainty. Engineering applications of artificial intelligence, 71, 236–250. https://doi.org/10.1016/j.engappai.2018.03.004
[51]   Yazdani, M., Torkayesh, A. E., & Chatterjee, P. (2020). An integrated decision-making model for supplier evaluation in public healthcare system: the case study of a Spanish hospital. Journal of enterprise information management. https://doi.org/10.1108/JEIM-09-2019-0294
[52]   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. https://doi.org/10.1007/s10098-021-02266-x
[53]   Nayeri, S., Sazvar, Z., & Heydari, J. (2023). Designing an IoT-enabled supply chain network considering the perspective of the fifth industrial revolution: Application in the medical devices industry. Engineering applications of artificial intelligence, 122, 106113. https://doi.org/10.1016/j.engappai.2023.106113
[54]   Fallahpour, A., Nayeri, S., Sheikhalishahi, M., Wong, K. Y., Tian, G., & Fathollahi-Fard, A. M. (2021). A hyper-hybrid fuzzy decision-making framework for the sustainable-resilient supplier selection problem: A case study of Malaysian Palm oil industry. Environmental science and pollution research. https://doi.org/10.1007/s11356-021-12491-y
[55]   Urata, T., Yamada, T., Itsubo, N., & Inoue, M. (2017). Global supply chain network design and Asian analysis with material-based carbon emissions and tax. Computers & industrial engineering, 113, 779–792. https://doi.org/10.1016/j.cie.2017.07.032
[56]   Moheb-Alizadeh, H., & Handfield, R. (2019). Sustainable supplier selection and order allocation: A novel multi-objective programming model with a hybrid solution approach. Computers & industrial engineering, 129, 192–209. https://doi.org/10.1016/j.cie.2019.01.011
[57]   Muthuswamy., M., & Ali, A. (2023). Sustainable supply chain management in the age of machine intelligence: addressing challenges, capitalizing on opportunities, and shaping the future landscape. Sustainable machine intelligence journal, 3, 1–4. https://doi.org/10.61185/SMIJ.2023.33103
[58]   Ghazvinian, A., Feng, B., Feng, J., Talebzadeh, H., & Dzikuć, M. (2024). Lean, agile, resilient, green, and sustainable (LARGS) supplier selection using multi-criteria structural equation modeling under fuzzy environments. Sustainability 2024, 16(4), 1594. https://doi.org/10.3390/SU16041594
[59]   Asadi, Z., Aghajani, H., Khatir, M. V., & Tirkolaee, E. B. (2025). Viable-sustainable supplier selection and order allocation problem considering Industry 5.0 pillars under mixed uncertainty. International journal of production research, 1–26. https://doi.org/10.1080/00207543.2025.2502848
[60]   Nayeri, S., Zhain, V. M., Asadi, Z., Sazvar, Z., Javadian, N., & others. (2024). Raw material provider selection problem considering the digitalization, circular economy and resilience dimensions: a case study. International journal of industrial engineering & production research, 35(3), 1–20. https://doi.org/10.22068/ijiepr.35.3.1997
[61]   Sahebjamnia, N. (2020). Resilient supplier selection and order allocation under uncertainty. Scientia iranica, 27(1 E). https://doi.org/10.24200/SCI.2018.5547.1337
[62]   Zekhnini, K., Cherrafi, A., Bouhaddou, I., Benghabrit, Y., & Garza-Reyes, J. A. (2020). Supplier selection for smart supply chain: An adaptive fuzzy-neuro approach. Proceedings of the international conference on industrial engineering and operations management. IEOM Society International.  https://www.researchgate.net/publication/352159349
[63]   Agarwal, R., & Nishad, A. K. (2024). A fuzzy mathematical modeling for evaluation and selection of a best sustainable and resilient supplier by using EDAS technique. Process integration and optimization for sustainability, 8(1), 71–80. https://doi.org/10.1007/s41660-023-00352-9
[64]   Davoudabadi, R., Mousavi, S. M., Mohagheghi, V., & Vahdani, B. (2019). Resilient supplier selection through introducing a new interval-valued intuitionistic fuzzy evaluation and decision-making framework. Arabian journal for science and engineering, 44(8), 7351–7360. https://doi.org/10.1007/s13369-019-03891-x
[65]   Mansory, A., Nasiri, A., & Mohammadi, N. (2021). Proposing an integrated model for evaluation of green and resilient suppliers by path analysis, SWARA and TOPSIS. Journal of applied research on industrial engineering, 8(2), 129–149. https://doi.org/10.22105/jarie.2021.256316.1206
[66]   Chaouni Benabdellah, G., Bennis, K., Chaouni Benabdellah, A., & Zekhnini, K. (2022). Resilient sustainable supplier selection criteria assessment for economics enhancement in industry 4.0 context [presentation]. IFIP advances in information and communication technology. https://doi.org/10.1007/978-3-030-94335-6_14
[67]   Sun, L., Yu, C., Li, J., Yuan, Q., & Zhao, S. (2025). A two-stage decision model for sustainable-resilient supplier selection and order allocation under uncertain environment. Kybernetes, 54(8), 4078–4113. https://doi.org/10.1108/K-11-2023-2347
[68]   Kumar, D., Soni, G., Joshi, R., Jain, V., & Sohal, A. (2022). Modelling supply chain viability during COVID ‑ 19 disruption : A case of an Indian automobile manufacturing supply chain. Operations management research, 1224–1240. https://doi.org/10.1007/s12063-022-00277-5
[69]   Wilhelm, W., Liang, D., Rao, B., Warrier, D., Zhu, X., & Bulusu, S. (2005). Design of international assembly systems and their supply chains under NAFTA. Transportation research part e: logistics and transportation review, 41(6), 467–493. https://doi.org/10.1016/j.tre.2005.06.002
[70]   Zhao, P., Ji, S., & Xue, Y. (2023). An integrated approach based on the decision-theoretic rough set for resilient-sustainable supplier selection and order allocation. Kybernetes, 52(3), 774–808. https://doi.org/10.1108/K-11-2020-0821
[71]   Sazvar, Z., Tavakoli, M., Ghanavati-Nejad, M., & Nayeri, S. (In Press). Sustainable-resilient supplier evaluation for high-consumption drugs during COVID-19 pandemic using a data-driven decision-making approach. Scientia iranica. https://doi.org/10.24200/sci.2022.59789.6424
[72]   Yadav, G., Kumar, A., Luthra, S., Garza-Reyes, J. A., Kumar, V., & Batista, L. (2020). A framework to achieve sustainability in manufacturing organisations of developing economies using industry 4.0 technologies’ enablers. Computers in industry, 122, 103280. https://doi.org/10.1016/j.compind.2020.103280
[73]   Kumar, V. (2024). Income prediction using machine learning. Soft computing fusion with applications, 1(3), 152–162. https://doi.org/10.22105/scfa.v1i3.46
Journal of Quality Engineering and Management
Volume 15, Issue 1
Spring 2025
Pages 83-109

Home

Editorial Board

Indexing and Abstracting

Guide for Authors

Submit Manuscript

Reviewers

Contact Us