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In game theory, the stag hunt, sometimes referred to as the assurance game, trust dilemma or common interest game, describes a conflict between safety and social cooperation. The stag hunt problem originated with philosopher Jean-Jacques Rousseau in his Discourse on Inequality. In the most common account of this dilemma, which is quite different from Rousseau's, two hunters must decide separately, and without the other knowing, whether to hunt a stag or a hare. However, both hunters know the only way to successfully hunt a stag is with the other's help. One hunter can catch a hare alone with less effort and less time, but it is worth far less than a stag and has much less meat. But both hunters would be better off if both choose the more ambitious and more rewarding goal of getting the stag, giving up some autonomy in exchange for the other hunter's cooperation and added might. This situation is often seen as a useful analogy for many kinds of social cooperation, such as international agreements on climate change.^[1]

The stag hunt differs from the prisoner's dilemma in that there are two pure-strategy Nash equilibria:^[2] one where both players cooperate, and one where both players defect. In the Prisoner's Dilemma, in contrast, despite the fact that both players cooperating is Pareto efficient, the only pure Nash equilibrium is when both players choose to defect.

An example of the payoff matrix for the stag hunt is pictured in Figure 2.

	Stag	Hare
Stag	a, a	c, b
Hare	b, c	d, d
Fig. 1: Generic symmetric stag hunt

	Stag	Hare
Stag	10, 10	1, 8
Hare	8, 1	5, 5
Fig. 2: Stag hunt example

Formal definition[edit]

Formally, a stag hunt is a game with two pure strategy Nash equilibria—one that is risk dominant and another that is payoff dominant. The payoff matrix in Figure 1 illustrates a generic stag hunt, where $a>b\geq d>c$ . Often, games with a similar structure but without a risk dominant Nash equilibrium are called assurance games. For instance if a=10, b=5, c=0, and d=2.^[3] While (Hare, Hare) remains a Nash equilibrium, it is no longer risk dominant. Nonetheless many would call this game a stag hunt.

In addition to the pure strategy Nash equilibria there is one mixed strategy Nash equilibrium. This equilibrium depends on the payoffs, but the risk dominance condition places a bound on the mixed strategy Nash equilibrium. No payoffs (that satisfy the above conditions including risk dominance) can generate a mixed strategy equilibrium where Stag is played with a probability higher than one half. The best response correspondences are pictured here.

The stag hunt and social cooperation[edit]

Although most authors focus on the prisoner's dilemma as the game that best represents the problem of social cooperation, some authors believe that the stag hunt represents an equally (or more) interesting context in which to study cooperation and its problems (for an overview see Skyrms 2004).

There is a substantial relationship between the stag hunt and the prisoner's dilemma. In biology many circumstances that have been described as prisoner's dilemma might also be interpreted as a stag hunt, depending on how fitness is calculated.

	Cooperate	Defect
Cooperate	2, 2	0, 3
Defect	3, 0	1, 1
Fig. 3: Prisoner's dilemma example

It is also the case that some human interactions that seem like prisoner's dilemmas may in fact be stag hunts. For example, suppose we have a prisoner's dilemma as pictured in Figure 3. The payoff matrix would need adjusting if players who defect against cooperators might be punished for their defection. For instance, if the expected punishment is −2, then the imposition of this punishment turns the above prisoner's dilemma into the stag hunt given at the introduction.

Examples of the stag hunt[edit]

The original stag hunt dilemma is as follows: a group of hunters have tracked a large stag, and found it to follow a certain path. If all the hunters work together, they can kill the stag and all eat. If they are discovered, or do not cooperate, the stag will flee, and all will go hungry.

The hunters hide and wait along a path. An hour goes by, with no sign of the stag. Two, three, four hours pass, with no trace. A day passes. The stag may not pass every day, but the hunters are reasonably certain that it will come. However, a hare is seen by all hunters moving along the path.

If a hunter leaps out and kills the hare, he will eat, but the trap laid for the stag will be wasted and the other hunters will starve. There is no certainty that the stag will arrive; the hare is present. The dilemma is that if one hunter waits, he risks one of his fellows killing the hare for himself, sacrificing everyone else. This makes the risk twofold; the risk that the stag does not appear, and the risk that another hunter takes the kill.

In addition to the example suggested by Rousseau, David Hume provides a series of examples that are stag hunts. One example addresses two individuals who must row a boat. If both choose to row they can successfully move the boat. However, if one doesn't, the other wastes his effort. Hume's second example involves two neighbors wishing to drain a meadow. If they both work to drain it they will be successful, but if either fails to do his part the meadow will not be drained.

Several animal behaviors have been described as stag hunts. One is the coordination of slime molds. In times of stress, individual unicellular protists will aggregate to form one large body. Here if they all act together they can successfully reproduce, but success depends on the cooperation of many individual protozoa. Another example is the hunting practices of orcas (known as carousel feeding). Orcas cooperatively corral large schools of fish to the surface and stun them by hitting them with their tails. Since this requires that the fish have no way to escape, it requires the cooperation of many orcas.

Author James Cambias describes a solution to the game as the basis for an extraterrestrial civilization in his 2014 science fiction book A Darkling Sea. Carol M. Rose argues that the stag hunt theory is useful in 'law and humanities' theory.^[4] In international law, countries are the participants in a stag hunt.^[5] They can, for example, work together to improve good corporate governance.^[6]

A stag Hunt with pre-play communication[edit]

Robert Aumann proposed: "Let us now change the scenario by permitting pre-play communication. On the face of it, it seems that the players can then 'agree' to play (c,c); though the agreement is not enforceable, it removes each player's doubt about the other one playing c".^[7] Aumann concluded that in this game "agreement has no effect, one way or the other." It is his argument: "The information that such an agreement conveys is not that the players will keep it (since it is not binding), but that each wants the other to keep it." In this game "each player always prefers the other to play c, no matter what he himself plays. Therefore, an agreement to play (c,c) conveys no information about what the players will do, and cannot be considered self-enforcing." Weiss and Agassi wrote about this argument: "This we deem somewhat incorrect since it is an oversight of the agreement that may change the mutual expectations of players that the result of the game depends on... Aumann’s assertion that there is no a priori reason to expect agreement to lead to cooperation requires completion; at times, but only at times, there is a posteriori reason for that... How a given player will behave in a given game, thus, depends on the culture within which the game takes place".^[8]

References[edit]

Notes

^ david1gibbon (February 11, 2013). "Uses of Game Theory in International Relations". Economic Theory of Networks at Temple University.{{cite web}}: CS1 maint: numeric names: authors list (link)
^ Fang C, Kimbrough SO, Pace S, Valluri A, Zheng Z (2002). "On Adaptive Emergence of Trust Behavior in the Game of Stag Hunt". Group Decision and Negotiation. 11 (6): 449–467. doi:10.1023/A:1020639132471. S2CID 7187903. Retrieved 2022-07-07.
^ In this symmetric case risk dominance occurs if (c – d)²≥(b – a)².
^ Rose, C. (2010). "Game Stories". Yale Journal of Law & the Humanities. 22: 369–391.
^ Nissen, A. (2021). "Stag Hunt: Anti-Corruption Disclosures Concerning Natural Resources" (PDF). Chicago Journal of International Law. 1: 1–20.
^ Nissen, A. (2021). "Stag Hunt: Anti-Corruption Disclosures Concerning Natural Resources" (PDF). Chicago Journal of International Law. 1: 1–20.
^ Robert J Aumann, "Nash Equilibria are not Self-Enforcing," in Economic Decision Making: Games, Econometrics and Optimisation (Essays in Honor of Jacques Dreze), edited by J. J. Gabszewicz, J.-F. Richard, and L. Wolsey, Elsevier Science Publishers, Amsterdam, 1990, pp. 201-206.
^ Weiss, Uri, and Joseph Agassi. "Game Theory for International Accords." SCJ Int'l L. & Bus. 16 (2019): 1.

Bibliography

Skyrms, Brian (2004). The Stag Hunt and the Evolution of Social Structure. Cambridge University Press.

External links[edit]

The stag hunt at GameTheory.net
Skyrms, Brian (March 2001). The stag hunt (PDF) (Written speech). Pacific Division of the American Philosophical Association – Presidential Address. Retrieved 2022-07-07.

[1] vid1gibbon (February 11, 2013). "Uses of Game Theory in International Relations". Economic Theory of Networks at Temple University.{{cite web}}: CS1 maint: numeric names: authors list (link)

[2] Fang C, Kimbrough SO, Pace S, Valluri A, Zheng Z (2002). "On Adaptive Emergence of Trust Behavior in the Game of Stag Hunt". Group Decision and Negotiation. 11 (6): 449–467. doi:10.1023/A:1020639132471. S2CID 7187903. Retrieved 2022-07-07.

[3] In this symmetric case risk dominance occurs if (c – d)²≥(b – a)².

[4] Rose, C. (2010). "Game Stories". Yale Journal of Law & the Humanities. 22: 369–391.

[5] Nissen, A. (2021). "Stag Hunt: Anti-Corruption Disclosures Concerning Natural Resources" (PDF). Chicago Journal of International Law. 1: 1–20.

[6] Nissen, A. (2021). "Stag Hunt: Anti-Corruption Disclosures Concerning Natural Resources" (PDF). Chicago Journal of International Law. 1: 1–20.

[7] Robert J Aumann, "Nash Equilibria are not Self-Enforcing," in Economic Decision Making: Games, Econometrics and Optimisation (Essays in Honor of Jacques Dreze), edited by J. J. Gabszewicz, J.-F. Richard, and L. Wolsey, Elsevier Science Publishers, Amsterdam, 1990, pp. 201-206.

[8] Weiss, Uri, and Joseph Agassi. "Game Theory for International Accords." SCJ Int'l L. & Bus. 16 (2019): 1.

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Topics in 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
Equilibrium concepts	Bayes correlated equilibrium Bayesian Nash equilibrium Berge equilibrium Core Correlated 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
Strategies	Backward induction Bid shading Collusion Forward induction Grim trigger Markov strategy Dominant strategies Pure strategy Mixed strategy Strategy-stealing argument Tit for tat
Classes of games	Bargaining problem Cheap talk Global game Intransitive game Mean-field game Mechanism design n-player game Perfect information Large Poisson game Potential game Repeated game Screening game Signaling game Stackelberg competition Strictly determined game Stochastic game Symmetric game Zero-sum game
Games	Go Chess Infinite chess Checkers Tic-tac-toe 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 Rock paper scissors Pirate game Dictator game Public goods game Blotto game War of attrition El Farol Bar problem Fair division Fair cake-cutting Cournot game 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	Arrow's impossibility theorem 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
Miscellaneous	All-pay auction Alpha–beta pruning Bertrand paradox Bounded rationality Combinatorial game theory Confrontation analysis Coopetition Evolutionary game theory First-move advantage in chess Glossary of game theory List of game theorists List of games in game theory No-win situation Solving chess Topological game Tragedy of the commons Tyranny of small decisions

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