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	Prize Fight	Ballet
Prize Fight	10,7	0,0
Ballet	0,0	7,10
Battle of the Sexes (1)

	Prize Fight	Ballet
Prize Fight	10,7	2,2
Ballet	0,0	7,10
Battle of the Sexes (2)

In game theory, the battle of the sexes is a two-player coordination game that also involves elements of conflict. The game was introduced in 1957 by R. Duncan Luce and Howard Raiffa in their classic book, Games and Decisions.^[1] Some authors prefer to avoid assigning sexes to the players and instead use Players 1 and 2, and some refer to the game as Bach or Stravinsky, using two concerts as the two events.^[2] The game description here follows Luce and Raiffa's original story.

Imagine that a man and a woman hope to meet this evening, but have a choice between two events to attend: a prize fight and a ballet. The man would prefer to go to prize fight. The woman would prefer the ballet. Both would prefer to go to the same event rather than different ones. If they cannot communicate, where should they go?

The payoff matrix labeled "Battle of the Sexes (1)" shows the payoffs when the man chooses a row and the woman chooses a column. In each cell, the first number represents the man's payoff and the second number the woman's.

This standard representation does not account for the additional harm that might come from not only going to different locations, but going to the wrong one as well (e.g. the man goes to the ballet while the woman goes to the prize fight, satisfying neither). To account for this, the game would be represented in "Battle of the Sexes (2)", where the players each have a payoff of 2 because they at least get to attend their favored events.

Equilibrium analysis

This game has two pure strategy Nash equilibria, one where both players go to the prize fight, and another where both go to the ballet. There is also a mixed strategy Nash equilibrium, in which the players randomize using specific probabilities. For the payoffs listed in Battle of the Sexes (1), in the mixed strategy equilibrium the man goes to the prize fight with probability 3/5 and the woman to the ballet with probability 3/5, so they end up together at the prize fight with probability 6/25 = (3/5)(2/5) and together at the ballet with probability 6/25 = (2/5)(3/5).

This presents an interesting case for game theory since each of the Nash equilibria is deficient in some way. The two pure strategy Nash equilibria are unfair; one player consistently does better than the other. The mixed strategy Nash equilibrium is inefficient: the players will miscoordinate with probability 13/25, leaving each player with an expected return of 6/5 (less than the payoff of 2 from each's less favored pure strategy equilibrium). It remains unclear how expectations would form that would result in a particular equilibrium being played out.

One possible resolution of the difficulty involves the use of a correlated equilibrium. In its simplest form, if the players of the game have access to a commonly observed randomizing device, then they might decide to correlate their strategies in the game based on the outcome of the device. For example, if the players could flip a coin before choosing their strategies, they might agree to correlate their strategies based on the coin flip by, say, choosing ballet in the event of heads and prize fight in the event of tails. Notice that once the results of the coin flip are revealed neither player has any incentives to alter their proposed actions if they believe the other will not. The result is that perfect coordination is always achieved and, prior to the coin flip, the expected payoffs for the players are exactly equal. It remains true, however, that even if there is a correlating device, the Nash equilibria in which the players ignore it will remain; correlated equilibria require both the existence of a correlating device and the expectation that both players will use it to make their decision.

Notes

^ Luce, R.D. and Raiffa, H. (1957) Games and Decisions: An Introduction and Critical Survey, Wiley & Sons (see Chapter 5, section 3).
^ Osborne, Martin and Ariel Rubinstein (1994). A Course in Game Theory. The MIT Press.

References

Fudenberg, D. and Tirole, J. (1991) Game theory, MIT Press. (see Chapter 1, section 2.4)
Kelsey, D. and S. le Roux (2015): An Experimental Study on the Effect of Ambiguity in a Coordination Game, Theory and Decision.

External links

GameTheory.net
Cooperative Solution with Nash Function by Elmer G. Wiens

[1] Luce, R.D. and Raiffa, H. (1957) Games and Decisions: An Introduction and Critical Survey, Wiley & Sons (see Chapter 5, section 3).

[2] Osborne, Martin and Ariel Rubinstein (1994). A Course in Game Theory. The MIT Press.

[1]

[2]

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 One possible resolution of the difficulty involves the use of a [[correlated equilibrium]]. In its simplest form, if the players of the game have access to a commonly observed randomizing device, then they might decide to correlate their strategies in the game based on the outcome of the device. For example, if the players could flip a coin before choosing their strategies, they might agree to correlate their strategies based on the coin flip by, say, choosing ballet in the event of heads and prize fight in the event of tails. Notice that once the results of the coin flip are revealed neither player has any incentives to alter their proposed actions if they believe the other will not. The result is that perfect coordination is always achieved and, prior to the coin flip, the expected payoffs for the players are exactly equal. It remains true, however, that even if there is a correlating device, the [[Nash equilibria]] in which the players ignore it will remain; correlated equilibria require both the existence of a correlating device and the expectation that both players will use it to make their decision.
-== Burning money ==
-{|align=right
-|
-{{Payoff matrix | Name = Unburned
-                | 2L = Prize Fight | 2R = Ballet |
-U = Prize Fight | UL = 4,1        | UR = 0,0        |
-D = Ballet | DL = 0,0        | DR = 1,4        |
-Float = none    }}
-|
-{{Payoff matrix | Name = Burned
-                | 2L = Prize Fight | 2R = Ballet |
-U = Prize Fight | UL = 2,1        | UR = -2,0       |
-D = Ballet | DL = -2,0       | DR = -1,4       |
-Float = none    }}
-|}
-Interesting strategic changes can take place in this game if one allows one player the option of "[[money burning|burning money]]" – that is, allowing that player to destroy some of their utility.  Consider the battle of the sexes here (called ''Unburned'').  Before making  his decision, the man (the row player) can, in view of the woman (the column player), choose to set fire to 2 payoff points, leading to the ''Burned'' subgame payoffs pictured to the right. The man and woman then simultaneously and independently choose ''Prize Fight'' or ''Ballet''.
-If one [[dominance (game theory)|iteratively deletes weakly dominated strategies]] then one arrives at a unique solution where the man '''does not''' burn the money and both players choose  ''Prize Fight''. The odd thing about this result is that by simply having the opportunity to burn money (but not actually using it), the man is able to secure his favored equilibrium.  The reasoning that results in this conclusion is known as [[solution concept#Forward induction|forward induction]] and is somewhat controversial.<ref>For a detailed explanation, see [http://www.umass.edu/preferen/Game%20Theory%20for%20the%20Behavioral%20Sciences/BOR%20Public/BOR%20Rationalizability.pdf] {{Webarchive|url=https://web.archive.org/web/20121015145548/http://www.umass.edu/preferen/Game%20Theory%20for%20the%20Behavioral%20Sciences/BOR%20Public/BOR%20Rationalizability.pdf |date=2012-10-15 }} p8 Section 4.5.</ref> Loosely, if the woman sees the man burn the money, she would think that he is doing so only because he is convinced it would make her choose ''Prize Fight''. She should also think, however, that if he could so convince her but he does not burn the money, he must think that she is going to choose ''Prize Fight'' anyway.
 == Notes ==

v t e Topics of game theory
Definitions	Congestion game Cooperative game Determinacy Escalation of commitment Extensive-form game First-player and second-player win Game complexity Graphical game Hierarchy of beliefs Information set Normal-form game Preference Sequential game Simultaneous game Simultaneous action selection Solved game Succinct game Mechanism design
Equilibrium concepts	Bayes correlated equilibrium Bayesian Nash equilibrium Berge equilibrium Core Correlated equilibrium Coalition-proof Nash equilibrium Epsilon-equilibrium Evolutionarily stable strategy Gibbs equilibrium Mertens-stable equilibrium Markov perfect equilibrium Nash equilibrium Pareto efficiency Perfect Bayesian equilibrium Proper equilibrium Quantal response equilibrium Quasi-perfect equilibrium Risk dominance Satisfaction equilibrium Self-confirming equilibrium Sequential equilibrium Shapley value Strong Nash equilibrium Subgame perfection Trembling hand equilibrium
Strategies	Appeasement Backward induction Bid shading Collusion Cheap talk De-escalation Deterrence Escalation Forward induction Grim trigger Markov strategy Pairing strategy Dominant strategies Pure strategy Mixed strategy Strategy-stealing argument Tit for tat
Classes of games	Auction Bargaining problem Global game Intransitive game Mean-field game n-player game Perfect information Large Poisson game Potential game Repeated game Screening game Signaling game Strictly determined game Stochastic game Symmetric game Zero-sum game
Games	Go Chess Infinite chess Checkers All-pay auction Prisoner's dilemma Gift-exchange game Optional prisoner's dilemma Traveler's dilemma Coordination game Chicken Centipede game Lewis signaling game Volunteer's dilemma Dollar auction Battle of the sexes Stag hunt Matching pennies Ultimatum game Electronic mail game Rock paper scissors Pirate game Dictator game Public goods game Blotto game War of attrition El Farol Bar problem Fair division Fair cake-cutting Bertrand competition Cournot competition Stackelberg competition Deadlock Diner's dilemma Guess 2/3 of the average Kuhn poker Nash bargaining game Induction puzzles Trust game Princess and monster game Rendezvous problem
Theorems	Aumann's agreement theorem Folk theorem Minimax theorem Nash's theorem Negamax theorem Purification theorem Revelation principle Sprague–Grundy theorem Zermelo's theorem
Key figures	Albert W. Tucker Amos Tversky Antoine Augustin Cournot Ariel Rubinstein Claude Shannon Daniel Kahneman David K. Levine David M. Kreps Donald B. Gillies Drew Fudenberg Eric Maskin Harold W. Kuhn Herbert Simon Hervé Moulin John Conway Jean Tirole Jean-François Mertens Jennifer Tour Chayes John Harsanyi John Maynard Smith John Nash John von Neumann Kenneth Arrow Kenneth Binmore Leonid Hurwicz Lloyd Shapley Melvin Dresher Merrill M. Flood Olga Bondareva Oskar Morgenstern Paul Milgrom Peyton Young Reinhard Selten Robert Axelrod Robert Aumann Robert B. Wilson Roger Myerson Samuel Bowles Suzanne Scotchmer Thomas Schelling William Vickrey
Search optimizations	Alpha–beta pruning Aspiration window Principal variation search max^n algorithm Paranoid algorithm Lazy SMP
Miscellaneous	Bounded rationality Combinatorial game theory Confrontation analysis Coopetition Evolutionary game theory Glossary of game theory List of game theorists List of games in game theory No-win situation Topological game Tragedy of the commons