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ECO290E: Game Theory

This lecture provides an overview of game theory, focusing on static games and Nash equilibrium. It discusses the normal form representation of games, the concept of Nash equilibrium, and various examples and applications.

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ECO290E: Game Theory

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  1. ECO290E: Game Theory Lecture 2 Static Games and Nash Equilibrium Lecture 2

  2. Review of Lecture 1 Game Theory • studies strategically inter-dependent situations. • provides us tools for analyzing most of problems in social science. • employs Nash equilibrium as a solution concept. • creates a revolution in Economics. Lecture 2

  3. What is Game? Lecture 2

  4. Games in Two Forms • Static games • The normal/strategic-form representation • Dynamic games • The extensive-form representation • In principle, static (/ dynamic) games can also be analyzed in an extensive-form (/a normal-form) representation. Lecture 2

  5. Normal-form Games The normal-form (strategic-form) representation of a game specifies: • The players in the game. • The strategies available to each player. • The payoff received by each player (for each combination of strategies that could be chosen by the players). Lecture 2

  6. Static Games • In a normal-form representation, each player simultaneously chooses a strategy, and the combination of strategies chosen by the players determines a payoff for each player. • The players do not necessarily act simultaneously: it suffices that each chooses her own action without knowing others’ choices. • We will also study dynamic games in an extensive-form representation later. Lecture 2

  7. Example: Prisoners’ Dilemma • Two suspects are charged with a joint clime, and are held separately by the police. • Each prisoner is told the following: 1) If one prisoner confesses and the other one does not, the former will be given a reward of 1 and the latter will receive a fine equal to 2. 2) If both confess, each will receive a fine equal to 1. 3) If neither confesses, both will be set free. Lecture 2

  8. Payoff Bi-Matrix Lecture 2

  9. How to Use Bi-Matrices • Any two players game (with finite number of strategies) can be expressed as a bi-matrix. • The payoffs to the two players when a particular pair of strategies is chosen are given in the appropriate cell. • The payoff to the row player (player 1) is given first, followed by the payoff to the column player (player 2). • How can we solve this game? Lecture 2

  10. Definition of Nash Equilibrium Nash equilibrium (mathematical definition) • A strategy profile s* is called a Nash equilibrium if and only if the following condition is satisfied: • Nash equilibrium is defined over strategy profiles, NOT over individual strategies. Lecture 2

  11. Solving PD Game • For each player, u(C,C)>u(S,C) holds. • (Confess, Confess) is a NE. • There is no other equilibrium. • Playing “Confess” is optimal no matter how the opponent takes “Confess” or “Silent.” • “Confess” is a dominant strategy. • The NE is not (Pareto) efficient. • Optimality for individuals does not necessary imply optimality for a group (society). Lecture 2

  12. Terminology Dominant strategy: • A strategy s is called a dominant strategy if playing s is optimal for any combination of other players’ strategies. Pareto efficiency: • An outcome of games is Pareto efficient if it is not possible to make one person better off (through moving to another outcome) without making someone else worse off. Lecture 2

  13. Applications of PD Lecture 2

  14. Example: Coordination Game Lecture 2

  15. Solving Coordination Game • There are two equilibria, (W,W) and (M,M). • Games, in general, can have more than one Nash equilibrium. • Everybody prefers one equilibrium (M,M) to the other (W,W). • Several equilibria can be Pareto-ranked. • However, bad equilibrium can be chosen. • This is called “coordination failure.” Lecture 2

  16. Other Examples • Battle of the sexes • Corruption Game • Stag Hunt Game • Migration Game • Hawk-Dove (Chicken) Game • Land Tenure Game Lecture 2

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