Blotto game

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A Blotto game, Colonel Blotto game, or divide-a-dollar game is a type of two-person zero-sum game in which the players are tasked to simultaneously distribute limited resources over several objects (or battlefields). In the classic version of the game, the player devoting the most resources to a battlefield wins that battlefield, and the gain (or payoff) is then equal to the total number of battlefields won.

The Colonel Blotto game was first proposed and solved by Émile Borel[1] in 1921, as an example of a game in which "the psychology of the players matters". It was studied after the Second World War by scholars in Operation Research, and became a classic in game theory.[2] It has been shown that finding a Min-Max equilibrium, or in other words, the optimal strategies of this game is computationally tractable.[3][4]

The game is named after the fictional Colonel Blotto from Gross and Wagner's 1950[5] paper. The Colonel was tasked with finding the optimum distribution of his soldiers over N battlefields knowing that:

  1. on each battlefield the party that has allocated the most soldiers will win, but
  2. neither party knows how many soldiers the opposing party will allocate to each battlefield, and:
  3. both parties seek to maximize the number of battlefields they expect to win.


As an example Blotto game, consider the game in which two players each write down three positive integers in non-decreasing order and such that they add up to a pre-specified number S. Subsequently, the two players show each other their writings, and compare corresponding numbers. The player who has two numbers higher than the corresponding ones of the opponent wins the game.

For S = 6 only three choices of numbers are possible: (2, 2, 2), (1, 2, 3) and (1, 1, 4). It is easy to see that:

Any triplet against itself is a draw
(1, 1, 4) against (1, 2, 3) is a draw
(1, 2, 3) against (2, 2, 2) is a draw
(2, 2, 2) beats (1, 1, 4)

It follows that the optimum strategy is (2, 2, 2) as it does not do worse than breaking even against any other strategy while beating one other strategy. There are however several Nash equilibria. If both players choose the strategy (2, 2, 2) or (1, 2, 3), then none of them can beat the other one by changing strategies, so every such strategy pair is a Nash equilibrium.

For larger S the game becomes progressively more difficult to analyze. For S = 12, it can be shown that (2, 4, 6) represents the optimal strategy, while for S > 12, deterministic strategies fail to be optimal. For S = 13, choosing (3, 5, 5), (3, 3, 7) and (1, 5, 7) with probability 1/3 each can be shown to be the optimal probabilistic strategy.

Borel's game is similar to the above example for very large S, but the players are not limited to round integers. They thus have an infinite number of available pure strategies, indeed a continuum.

This concept is also implemented in a story of Sun Bin when watching a chariot race with three different races running concurrently. In the races each party had the option to have one chariot team in each race, and each chose to use a strategy of 1, 2, 3 (with 3 being the fastest chariot and 1 being the slowest) to deploy their chariots between the three races creating close wins in each race and few sure outcomes on the winners. When asked how to win Sun Bin advised the chariot owner to change his deployment to that of 2, 3, 1. Though he would be sure to lose the race against the fastest chariots (the 3 chariots); he would win each of the other races, with his 3 chariot easily beating 2 chariots and his 2 chariot beating the 1 chariots.


This game is commonly used as a metaphor for electoral competition, with two political parties devoting money or resources to attract the support of a fixed number of voters.[6][7] Each voter is a "battlefield" that can be won by one or the other party. The same game also finds application in auction theory where bidders must make simultaneous bids.[8]

Several variations on the original game have been solved by Jean-François Laslier,[9] Brian Roberson,[10] Dmitriy Kvasov.[11].

See also[edit]


  1. ^ The Theory of Play and Integral Equations with Skew Symmetric Kernels (1953 translation from the French paper "La théorie du jeu et les équations intégrales à noyau symétrique gauche")
  2. ^ Guillermo Owen, Game Theory, Academic Press (1968)
  3. ^ mewright. "UMD-led Team First to Solve Well-known Game Theory Scenario". College of Computer, Mathematical, and Natural Sciences. Retrieved 2016-03-29.
  4. ^ Ahmadinejad, Mahdi; Dehghani, Sina; Hajiaghayi, MohammadTaghi; Lucier, Brendan; Mahini, Hamid; Seddighin, Saeed (2016). "From Duels to Battefields: Computing Equilibria of Blotto and Other Games". arXiv:1603.00119 [cs.GT].
  5. ^ A Continuous Colonel Blotto Game
  6. ^ R. Myerson "Incentives to cultivate favored minorities under alternative electoral systems" American Political Science Review 87(4):856—869, 1993
  7. ^ Laslier, J.-F.; Picard, N. (2002). "Distributive politics and electoral competition". Journal of Economic Theory. 103: 106–130. doi:10.1006/jeth.2000.2775.
  8. ^ Szentes, B.; Rosenthal, R. (2003). "Three-object, Two-Bidder Simultaneous Auctions: Chopsticks and Tetrahedra". Games and Economic Behavior. 44: 114–133. doi:10.1016/s0899-8256(02)00530-4.
  9. ^ J.-F. Laslier, "Party objectives in the `divide a dollar’ electoral competition" in: Social Choice and Strategic Decisions, Essays in Honor of Jeff Banks, edited by D. Austen–Smith and J. Duggan, Springer, pp. 113–130 (2005)
  10. ^ B. Roberson, The Colonel Blotto game[dead link]
  11. ^ Kvasov, D. (2007). "Contests with Limited Resources". Journal of Economic Theory. 136: 738–748. doi:10.1016/j.jet.2006.06.007.

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