A fuzzy interval based multi-criteria homogeneous group decision making technique: An application to airports ranking problem
DOI:
https://doi.org/10.31181/dmame622023410Keywords:
Airport selection, Decision making under uncertainty, Homogeneous Group decision making, FMCDMAbstract
This paper aims to develop and introduce a fuzzy Interval based Multi-criteria homogeneous Group Decision making technique (IMGD) to make appropriate decision under fuzzy environment. In fuzzy multi-criteria group decision making process, a group of decision makers often considers several subjective criteria for ranking a set of alternatives. Due to vague and imprecise information, decision makers generally utilize linguistic variables which are mandatorily converted into triangular or trapezoidal fuzzy numbers. The total process then becomes very complex and time consuming. The current investigation advocates fuzzy intervals instead of triangular or trapezoidal fuzzy numbers for simplification of the complex situation and ease of calculation. In this method, fuzzy intervals of performance ratings and weights assessed by homogeneous group decision makers under subjective criteria are converted into first mean fuzzy intervals then into normalized crisp numbers. The normalized crisp performance ratings and normalized crisp weights are combined together to determine initially individual contribution and then into aggregate contribution to each alternative for final ranking and selection of the alternative. The new model is demonstrated with an application to airports ranking and selection problem for better clarification and verification. The outcome of the proposed is validated with the results obtained by well-known existing MCDM techniques. The analysis shows that the proposed method is applicable, useful and effective for appropriate decision making under fuzzy MCDM environment.
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References
Bao, F. (2014). Research on Airport Site Selection Based on Triangular Fuzzy Number. Applied Mechanics and Materials, 507– 511.
Belbag, S., Deveci, M., & Uludag, A.S. (2013). Comparison of Two Fuzzy Multi Criteria Decision Methods for Potential Airport Location Selection. International Conference on Operations Research and Enterprise Systems, 122-128.
Zhao, B., Wang, N., Fu, Q., Yan, H.Q., Wu, N. (2019). Searching a site for a civil airport based on bird ecological conservation: An expert-based selection (Dalian, China). Global Ecology and Conservation, 20, e00729.
Bo, J., & Wang Yifei. (2014). The Evaluation of Airport Site Selection Based on the Multilayer Fuzzy Reasoning Model. International Conference of Logistics Engineering and Management, 836-841. DOI: 10.1061/9780784413753.126.
Carmona-benítez, R.B., Fernandez, O., & Segura, E. (2013). Site Selection of the New Mexico City Airport from the Perspective of Maximizing the Sum of Expected Air Pax Demand, Computational Logistics, 8197, 586–601.
Hammad, A.W.A., Akbarnezhad, A., & Rey, D. (2017). Bilevel Mixed-Integer Linear Programming Model for Solving the Single Airport Location Problem, Journal of Computing in Civil Engineering, 31(5), 3–7.
Merkisz-Guranowska, A. (2016). Location of Airports - Selected Quantitative Methods. Scientific Journal of Logistics, 12(3), 283–295.
Fu, Q., Wang, N., Shen, M.Q., Song, N.Q., & Yan, H.Q. (2016). A Study of The Site Selection of a Civil Airport Based on The Risk of Bird Strikes : The case of Dalian, China, Journal of Air Transport Management, 54, 17–30.
Postorino, M.N., & Praticò, F.G. (2012). An Application of The Multi-Criteria Decision ‐ Making Analysis to A Regional Multi-Airport System. Research in Transportation Business & Management (RTBM), 4, 44–52.
Sur, K.K., & Majumder, S.K. (2012). Construction of a New Airport in a Developing Country, Using Entropy Optimization Method to the Model. ICSRS Publication, 8(1), 29–34.
Yang, C., Wu, T., & Liao, Y. (2014). Evaluation for the Location Selection of Airport Based on WLSM- TOPSIS Method. Applied Mechanics and Materials, 1823–1827.
Yang, Z., Yu, S., & Notteboom, T. (2016). Airport Location in Multiple Airport Regions (MARs): The Role of Land and Airside Accessibility. Journal of Transport Geography JTRG, 52, 98–110.
Wang, Y.J., & Lee, H.S. (2007). Generalizing TOPSIS for fuzzy multiple-criteria group decision-making. Computers and Mathematics with Applications, 53, 1762–1772.
Zhao, S., & Sun, P. (2013). Scheme Comparison of New Airport Site Selection Based on Lattice Order Decision Making Method in The Integrated Transportation System. International Journal of online Engineering, 9, 95–99.
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