Mallozzi, Lina and Vidal-Puga, Juan (2024): An efficient Shapley value for games with fuzzy characteristic function.
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Abstract
We consider cooperative games where the characteristic function is valued in the space of the fuzzy numbers. By using different fuzzy calculation methods to transform the game into a crisp cooperative one, we define and characterize an efficient extension of the Shapley value. This solution is a relevant member of a wider family of more general, fuzzy calculation method dependent extensions of the Shapley value.
| Item Type: | MPRA Paper |
|---|---|
| Original Title: | An efficient Shapley value for games with fuzzy characteristic function |
| Language: | English |
| Keywords: | Cooperative game; Shapley value; fuzzy set; efficiency |
| Subjects: | C - Mathematical and Quantitative Methods > C7 - Game Theory and Bargaining Theory > C71 - Cooperative Games |
| Item ID: | 122168 |
| Depositing User: | Juan Vidal-Puga |
| Date Deposited: | 25 Sep 2024 06:55 |
| Last Modified: | 25 Sep 2024 06:55 |
| References: | Béal, S., Ferrières, S., Rémila, E., and Solal, P. (2018). The proportional Shapley value and applications. Games and Economic Behavior, 108:93–112. Special Issue in Honor of Lloyd Shapley: Seven Topics in Game Theory. Besner, M. (2019). Axiomatizations of the proportional Shapley value. Theory and Decision, 86:161–183. Borkotokey, S. and Mesiar, R. (2014). The Shapley value of cooperative games under fuzzy setting: A survey. International Journal of General Systems, 43(1):75–95. Cunlin, L. and Qiang, Z. (2011). Nash equilibrium strategy for fuzzy non-cooperative games. Fuzzy Sets and Systems, 176(1):46–55. Gallardo, J. and Jiménez-Losada, A. (2020). A characterization of the Shapley value for cooperative games with fuzzy characteristic function. Fuzzy Sets and Systems, 398:98–111. Kalai, E. and Samet, D. (1987). On weighted Shapley values. International Journal of Game Theory, 16(3):205–222. Mallozzi, L. and Vidal-Puga, J. (2023). Equilibrium and dominance in fuzzy games. Fuzzy Sets and Systems, 458:94–107. Mares, M. (2001). Fuzzy cooperative games. Physica-Verlag, Heidelberg. Mares, M. and Vlach, M. (2004). Fuzzy classes of cooperative games with trasferable utilities. Scientiae Mathematicae Japonicae Online, 10:197–206. Ortmann, K. (2000). The proportional value for positive cooperative games. Mathematical Methods of Operations Research, 51:235–248. Schmeidler, D. (1969). The nucleolus of a characteristic function game. SIAM Journal of Applied Mathematics, 17(6):1163–1170. Shapley, L. S. (1953). A value for n-person games. In Kuhn, H. and Tucker, A., editors, Contributions to the theory of games, volume II of Annals of Mathematics Studies, pages 307–317. Princeton University Press, Princeton NJ. Sivanandam, S. N. and Deepa, S. N. (2019). Principles of Soft Computing. Wiley, third edition. van den Brink, R. (2007). Null or nullifying players: The difference between the Shapley value and equal division solutions. Journal of Economic Theory, 136(1):767–775. van den Brink, R. and Funaki, Y. (2009). Axiomatizations of a class of equal surplus sharing solutions for TU-games. Theory and Decision, 67:303–340. van den Brink, R., Levı́nský, R., and Zelený, M. (2015). On proper Shapley values for monotone TU-games. International Journal of Game Theory, 44(2):449–471. Vorob’ev, N. and Liapounov, A. (1998). The proper Shapley value. In Petrosyan, L. and Mazalov, M., editors, Game Theory and Applications, volume IV, pages 155–159. Nova Science, New York. Yu, X. and Zhang, Q. (2010). An extension of cooperative fuzzy games. Fuzzy Sets and Systems, 161(11):1614–1634. Theme: Decision Systems. Zadeh, L. (1978). Fuzzy sets as a basis for a theory of possibility. Fuzzy Sets and Systems, 1:3–28. |
| URI: | https://mpra.ub.uni-muenchen.de/id/eprint/122168 |
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