Abstract
In this paper we develop an epistemic model for dynamic games in which players may revise their beliefs about the opponents’ utility functions as the game proceeds. Within this framework, we propose a rationalizability concept that is based upon the following three principles: (1) at every instance of the game, a player should believe that his opponents are carrying out optimal strategies, (2) a player, at information set h, should not change his belief about an opponent’s relative ranking of two strategies s and s′ if both s and s′ could have led to h, and (3) the players’ initial beliefs about the opponents’ utility functions should agree on a given profile u of utility functions. Common belief in these events leads to the concept of persistent rationalizability for the profile u of utility functions. It is shown that for a given game tree with observable deviators and a given profile u of utility functions, every properly point-rationalizable strategy is a persistently rationalizable strategy for u. This result implies that persistently rationalizable strategies always exist for all game trees with observable deviators and all profiles of utility functions. We provide an algorithm that can be used to compute the set of persistently rationalizable strategies for a given profile u of utility functions. For generic games with perfect information, persistent rationalizability uniquely selects the backward induction strategy for every player.
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References
Asheim GB (2001) Proper rationalizability in lexicographic beliefs. Int J Game Theory 30:453–478
Asheim GB (2002) On the epistemic foundation for backward induction. Math Soc Sci 44:121–144
Aumann R (1995) Backward induction and common knowledge of rationality. Games Econ Behav 8:6–19
Balkenborg D, Winter E (1997) A necessary and sufficient epistemic condition for playing backward induction. J Math Econ 27:325–345
Battigalli P (1996) Strategic independence and perfect Bayesian equilibria. J Econ Theory 70:201–234
Battigalli P (1997) On rationalizability in extensive games. J Econ Theory 74:40–61
Battigalli P, Siniscalchi M (1999) Hierarchies of conditional beliefs, and interactive epistemology in dynamic games. J Econ Theory 88:188–230
Battigalli P, Siniscalchi M (2002) Strong belief and forward induction reasoning. J Econ Theory 106:356–391
Ben-Porath E (1997) Rationality, Nash equilibrium and backwards induction in perfect-information games. Rev Econ Stud 64:23–46
Bernheim BD (1984) Rationalizable strategic behavior. Econometrica 52:1007–1028
Blume LE, Brandenburger A, Dekel E (1991a) Lexicographic probabilities and choice under uncertainty. Econometrica 59:61–79
Blume LE, Brandenburger A, Dekel E (1991b) Lexicographic probabilities and equilibrium refinements. Econometrica 59:81–98
Brandenburger A, Dekel E (1993) Hierarchies of beliefs and common knowledge. J Econ Theory 59:189–198
Dekel E, Fudenberg D (1990) Rational behavior with payoff uncertainty. J Econ Theory 52:243–267
Mertens J-F, Zamir S (1985) Formulation of bayesian analysis for games with incomplete information. Int J Game Theory 14:1–29
Myerson RB (1978) Refinements of the Nash equilibrium concept. Int J Game Theory 7:73–80
Pearce D (1984) Rationalizable strategic behavior and the problem of perfection. Econometrica 52:1029–1050
Perea A (2003) Proper rationalizability and belief revision in dynamic games. Available at the author’s website: http://www.personeel.unimaas.nl/a.perea/
Perea A (2006) Proper belief revision and equilibrium in dynamic games. J Econ Theory (forthcoming)
Reny PJ (1992a) Rationality in extensive-form games. J Econ Perspect 6:103–118
Reny PJ (1992b) Backward induction, normal form perfection and explicable equilibria. Econometrica 60:627–649
Reny PJ (1993) Common belief and the theory of games with perfect information. J Econ Theory 59:257–274
Rubinstein A (1991) Comments on the interpretation of game theory. Econometrica 59:909–924
Samet D (1996) Hypothetical knowledge and games with perfect information. Games Econ Behav 17:230–251
Schuhmacher F (1999) Proper rationalizability and backward induction. Int J Game Theory 28:599–615
Schulte O (2003) Iterated backward inference: an algorithm for proper rationalizability. In: Proceedings of TARK IX (theoretical aspects of reasoning about knowledge)
Stalnaker R (1998) Belief revision in games: forward and backward induction. Math Soc Sci 36: 31–56
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Perea, A. Proper belief revision and rationalizability in dynamic games. Int J Game Theory 34, 529–559 (2006). https://doi.org/10.1007/s00182-006-0031-8
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DOI: https://doi.org/10.1007/s00182-006-0031-8