A Comparative Assesment of Facility Location Problem via fuzzy TOPSIS and fuzzy VIKOR: A Case Study on Security Services
DOI:
https://doi.org/10.18533/ijbsr.v5i5.770Keywords:
Fuzzy TOPSIS, fuzzy VIKOR, law enforcement.Abstract
Today, law enforcement and security services are critically important for peace and prosperity of communities. The law enforcement forces serve citizens using security materials. The distribution of security materials is the dominant factor in determining the outcome of law enforcement duties. Failing to supply the required amounts of security materials properly, when and where it is needed, can lead to chaos. In this study, it is aimed to provide a decision support tool that can help to select the most appropriate location of security materials distribution center. The distribution center location problem is a complex multi-criteria problem including both quantitative and qualitative factors which may be in conflict and may also be uncertain. We proposed a comparative analysis that exploits fuzzy TOPSIS and fuzzy VIKOR techniques. Fuzzy weights of the 20 criteria and fuzzy judgments about 4 potential locations of distribution center as alternatives are employed to compute evaluation scores and ranking. Based on the evaluation criteria, Konya has been found the best alternative accourding to both techniques as well.
References
Amiri, M.P. (2010). Project selection for oil-.fields development by using the AHP and fuzzy TOPSIS methods. Expert Systems with Applications, 37, 6218-6224.
Ayag, Z. & Ozdemir, R.G. (2012). Evaluating machine tool alternatives through modified TOPSIS and alpha-cut based fuzzy ANP. International Journal of Production Economics, 140(2), 630-636.
Bell, J.E. (2003). A simulated annealing approach for the composite facility location and resource allocation problem: a study of strategic positioning of US Air Force munitions (No. C102-927). AUBURN UNIV AL.
Bellman, R.E. & Zadeh, L.A. (1970). Decision-making in a fuzzy environment. Management science, 17(4), 141-164.
Boran, F.E. (2011). An integrated intuitionistic fuzzy multi criteria decision making method for facility location selection. Mathematical and Computational Applications, 16(2), 487-496.
Buyukozkan, G., Feyzioglu, O. & Nebol, E. (2008). Selection of the strategic alliance partner in logistics value chain. International Journal of Production Economics, 113(1), 148-158.
Cagrici, H. (2007). Determining the Optimal Locations of Munitions’ Warehouse of the Multiple Launch Rocket Systems with Genetic Algoritms, Master Thesis, Turkish Army Military Academy Ankara, Turkey.
Chan, F.T. & Kumar, N. (2007). Global supplier development considering risk factors using fuzzy extended AHP-based approach. Omega, 35(4), 417-431.
Chang, Y.H., Yeh, C.H. & Wang, S.Y. (2007). A survey and optimization-based evaluation of development strategies for the air cargo industry. International Journal of Production Economics, 106(2), 550-562.
Chen, C.T. (2000). Extensions of the TOPSIS for group decision-making under fuzzy environment. Fuzzy sets and systems, 114(1), 1-9.
Chen, S.M. (1996). Evaluating weapon systems using fuzzy arithmetic operations. Fuzzy sets and systems, 77(3), 265-276.
Chen, T.Y. & Tsao, C.Y. (2008). The interval-valued fuzzy TOPSIS method and experimental analysis. Fuzzy Sets and Systems, 159(11), 1410-1428.
Cheng, C.H. & Lin, Y. (2002). Evaluating the best main battle tank using fuzzy decision theory with linguistic criteria evaluation. European Journal of Operational Research, 142(1), 174-186.
Chu, T.C. (2002). Selecting plant location via a fuzzy TOPSIS approach. The International Journal of Advanced Manufacturing Technology, 20(11), 859-864.
Cinar, N. & Ahiska, S.S. (2010). A decision support model for bank branch location selection. International Journal of Human and Social Sciences, 5(13), 846-851.
Dag, S. & Onder, E. (2013). Decision-Making for Facility Location Using Vikor Method. Journal of International Scientific Publications: Economy & Business, 7, 308-330.
Erdal, H. (2013). Optimization of Ammunition Distribution Network, Master Thesis, Turkish Army Military Academy, Ankara, Turkey.
Ertugrul, İ. & Karakasoglu, N. (2008). Comparison of fuzzy AHP and fuzzy TOPSIS methods for facility location selection. The International Journal of Advanced Manufacturing Technology, 39(7-8), 783-795.
Giachetti, R.E. & Young, R.E. (1997). A parametric representation of fuzzy numbers and their arithmetic operators. Fuzzy sets and systems, 91(2), 185-202.
Gue, K.R. (2003). A dynamic distribution model for combat logistics. Computers & Operations Research, 30(3), 367-381.
Kahraman, C., Beskese, A. & Ruan, D. (2004). Measuring flexibility of computer integrated manufacturing systems using fuzzy cash flow analysis. Information Sciences, 168(1), 77-94.
Kavitha, C. & Vijayalakshmi, C. (2010, December). Implementation of fuzzy multi criteria decision technique to identify the best location for call center. In Trendz in Information Sciences & Computing (TISC), 2010 (pp. 21-27). IEEE.
Li, Y., Liu, X. & Chen, Y. (2011). Selection of logistics center location using Axiomatic Fuzzy Set and TOPSIS methodology in logistics management. Expert Systems with Applications, 38(6), 7901-7908.
Liang, G.S. & Wang, M.J.J. (1993). A fuzzy multi-criteria decision-making approach for robot selection. Robotics and Computer-Integrated Manufacturing, 10(4), 267-274.
Liu, H.C., Wu, J. & Li, P. (2013). Assessment of health-care waste disposal methods using a VIKOR-based fuzzy multi-criteria decision making method. Waste management, 33(12), 2744-2751.
Melo, M.T., Nickel, S. & Saldanha-Da-Gama, F. (2009). Facility location and supply chain management–A review. European Journal of Operational Research, 196(2), 401-412.
Momeni, M., Fathi, M.R. & Kashef, M. (2011). A Fuzzy VIKOR Approach for Plant Location Selection. Journal of American Science, 7(9), 766-771.
Moon, J.H. & Kang, C.S. (2001). Application of fuzzy decision making method to the evaluation of spent fuel storage options. Progress in Nuclear Energy, 39(3), 345-351.
Opricovic, S. (1998). Multi-criteria optimization of civil engineering systems. Belgrade: Faculty of Civil Engineering.
Opricovic, S. & Tzeng, G.H. (2002). Multicriteria planning of post-earthquake sustainable reconstruction. Computer-Aided Civil and Infrastructure Engineering, 17(3), 211-220.
Opricovic, S. & Tzeng, G.H. (2004). Compromise solution by MCDM methods: a comparative analysis of VIKOR and TOPSIS. European Journal of Operational Research.156(2), 445-455.
Opricovic, S. & Tzeng, G.H. (2007). Extended VIKOR method in comparison with outranking methods. European Journal of Operational Research, 178, 514-529.
Onut, S. & Soner, S. (2008). Transshipment site selection using the AHP and TOPSIS approaches under fuzzy environment. Waste Management, 28(9), 1552-1559.
Patil, S.K. & Kant, R. (2014). A hybrid approach based on fuzzy DEMATEL and FMCDM to predict success of knowledge management adoption in supply chain. Applied Soft Computing, 18, 126-135.
Sabuncuoglu, I. & Utku, D.H. (2002, December). Logistics 2: evaluation of army corps artillery ammunition supply systems via simulation. In Proceedings of the 34th conference on Winter simulation: exploring new frontiers (pp. 917-920). Winter Simulation Conference.
Sahin, S. (2006). A Routing Model for Ammunition Transportation and Its Application, Master Thesis, Turkish Army Military Academy, Ankara, Turkey.
Shyur, H.J. & Shih, H. S. (2006). A hybrid MCDM model for strategic vendor selection. Mathematical and Computer Modeling, 44, 749–761.
Tang, Y.C. (2009). An approach to budget allocation for an aerospace company fuzzy analytic hierarchy process and artificial neural network. Neurocomputing, 72, 3477–3489.
Toyoglu, H., Karasan, O.E. & Kara, B.Y. (2011). Distribution network design on the battlefield. Naval Research Logistics (NRL), 58(3), 188-209.
Tsai, W.H., Chou, W.C. & Leu, J.D. (2011). An effectiveness evaluation model for the web-based marketing of the airline industry. Expert Systems with Applications, 38(12), 15499–15516.
Tsao, C.T. & Chu, T.C. (2001). Personnel selection using an improved fuzzy MCDM algorithm. Journal of Information & Optimization Sciences, 22(3), 521-536.
Tzeng, G.H., Lin, C.W. & Opricovic, S. (2005). Multi-criteria analysis of alternativefuel buses for public transportation. Energy Policy, 33(11), 1373–1383.
Verma, A.K., Verma, R. & Mahanti, N.C. (2010). Facility location selection: an interval valued intuitionistic fuzzy TOPSIS approach. Journal of Modern Mathematics and Statistics, 4(2), 68-72.
Wadhwa, S., Madaan, J. & Chan, F.T.S. (2009). Flexible decision modeling of reverse logistics system: A value adding MCDM approach for alternative selection. Robotics and Computer-Integrated Manufacturing, 25(2), 460-469.
Wang, Y.M. & Elhag, T.M.S. (2006). Fuzzy TOPSIS method based on alpha level sets with an application to bridge risk assessment. Expert Systems with Applications, 31, 309–319.
Uludag, A.S. & Deveci, M.E. (2013). Using the multi-crıteria decision making methods in facility location selection problems and an application, AİBÜ Journal of Social Science Institute, 13(1), 257- 287.
Yong, D. (2006). Plant location selection based on fuzzy TOPSIS. The International Journal of Advanced Manufacturing Technology, 28(7-8), 839-844.
Zadeh, L.A. (1965). Fuzzy Sets. Information and Control, 338-353.
Zadeh, L.A. (1974). The concept of a linguistic variable and its application to approximate reasoning (pp. 1-10). Springer US.
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