How long to equilibrium? The communication complexity of uncoupled equilibrium procedures

Sergiu Hart; Yishay Mansour

doi:10.1016/j.geb.2007.12.002

How long to equilibrium? The communication complexity of uncoupled equilibrium procedures

Sergiu Hart^*, Yishay Mansour

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

72 Scopus citations

Abstract

We study the question of how long it takes players to reach a Nash equilibrium in uncoupled setups, where each player initially knows only his own payoff function. We derive lower bounds on the communication complexity of reaching a Nash equilibrium, i.e., on the number of bits that need to be transmitted, and thus also on the required number of steps. Specifically, we show lower bounds that are exponential in the number of players in each one of the following cases: (1) reaching a pure Nash equilibrium; (2) reaching a pure Nash equilibrium in a Bayesian setting; and (3) reaching a mixed Nash equilibrium. We then show that, in contrast, the communication complexity of reaching a correlated equilibrium is polynomial in the number of players.

Original language	English
Pages (from-to)	107-126
Number of pages	20
Journal	Games and Economic Behavior
Volume	69
Issue number	1
DOIs	https://doi.org/10.1016/j.geb.2007.12.002
State	Published - May 2010

Keywords

Communication complexity
Correlated equilibrium
Nash equilibrium
Speed of convergence
Uncoupled dynamics

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AB - We study the question of how long it takes players to reach a Nash equilibrium in uncoupled setups, where each player initially knows only his own payoff function. We derive lower bounds on the communication complexity of reaching a Nash equilibrium, i.e., on the number of bits that need to be transmitted, and thus also on the required number of steps. Specifically, we show lower bounds that are exponential in the number of players in each one of the following cases: (1) reaching a pure Nash equilibrium; (2) reaching a pure Nash equilibrium in a Bayesian setting; and (3) reaching a mixed Nash equilibrium. We then show that, in contrast, the communication complexity of reaching a correlated equilibrium is polynomial in the number of players.

KW - Communication complexity

KW - Correlated equilibrium

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KW - Speed of convergence

KW - Uncoupled dynamics

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How long to equilibrium? The communication complexity of uncoupled equilibrium procedures

Abstract

Keywords

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