Question 1) Repeated Cournot
Consider a repeated version of the Cournot model discussed in class, with two firms i =1, 2, demand function
P (Q) = (A - Q)+,
marginal production costs ci > 0 (satisfying c1, c2 < A) and discount factor α ∈ (0, 1).
a) Find out a strategy profile that induced these firms to cooperate in this market (i.e., to collude by producing in total the monopoly quantity (A-c)/2) for sufficiently patient firms. How large does the discount factor δ needs to be to sustain cooperation?
b) Now suppose firms want to sustain cooperation in an asymmetric way. Describe a strategy profile that induces these firms to cooperate, for large enough discount factor δ, in an asymmetric way, i.e., to produce the monopoly quantity in total (which maximizes total profits in the stage game) with firm 1 producing share α1 ∈ (0, 1) of this quantity and firm 2 producing share α2 ∈ (0, 1) of this quantity, with α1 + α2 = 1. Suppose that α1 < α2. Find how large the discount factor δ needs to be for cooperation to be sustained (Hint: you can use modified grim-trigger strategies for this question).
Question 2) A simple bayesian game
Suppose players 1 and 2 have to jointly decide whether to go to a BC Lions (L) or Canucks (C) game.
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L
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C
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L
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4,1
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0,0
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C
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0,0
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1,4
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Table 1:
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a) What are the Nash equilibria of this game (pure and mixed)?
b) Let's turn this game into a Bayesian game. Now let's assume that player 2 might be a friend or a foe to player 1. If player 2 is a friend he has exactly the same pay-off as in item (a). If he is a foe, then he does not like to be together with player 1!. So player 2 gets a payoff of 4 if he goes to a Canucks game alone, a payoff of 1 if he goes to a BC Lions game alone, and a payoff of zero if he ends up in the same place as player 1. Player 2 is either a friend or foe with probability ½.
Player 1 is always a friend, and so has payoffs identical to the one presented in item (a). Formally describe the Bayesian game described (present all the elements that constitute a Bayesian Game).
c) What are the pure Bayes-Nash equilibria of this game?
Question 3) Prisoner dilemma with alternating actions
Consider the following version of the prisoner's dilemma:
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C
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D
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C
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4,4
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0,6
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D
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6,0
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1,1
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Table 2: Prisoner's dilemma
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Assume that the game represented is played for infinite periods, with discount factor δ ∈ [0, 1).
a) When can the cooperative outcome (C, C) be sustained via grim-trigger strategy profile?
b) Draw the set of feasible and individually rational payoffs.
c) What is the highest symmetric individually rational payoff profile (i.e., the highest payoff profile (v, v) consistent with feasibility and individual rationality)?
d) Consider the following modified grim-trigger strategy: both players alternate between the action profile (C,D) and (D,C) as long as everyone has followed this plan so far. If someone played differently, then play D forever.
Formally, let the set of alternating histories be (which includes the initial node)
HA = {Φ, (C, D) , ((C, D) , (D, C)) , ((C, D) , (D, C) , (C, D)) , . . .} .
The strategy profile proposed is (s1MGT, s2MGT) such that:
Player 1 plays as follows:
- s1MGT(ht) = C if ht ∈ HA and t is an odd number.
- s1MGT(ht) = D otherwise (i.e., if ht ∈ HA and t is even or ht ∉ HA).
Player 2 plays as follows:
- s2MGT (ht) = C if ht ∈ HA and t is an even number (including zero).
- s1MGT (ht) = D otherwise (i.e., if ht ∈ HA and t is odd or ht ∉ HA).
What is the average discounted payoff generated by this strategy profile?
e) Under what conditions is (s1MGT, s2MGT) a SPE?
Question 4) First price auction
Consider a first price auction in which two bidders are competing for one good. Each bidder has valuation vi distributed uniformly on [2, 3].
a) What are the elements that describe a Bayesian game? Describe all these elements for the auction described.
b) Find numbers α, β ≥ 0 such that both bidders using bidding strategy b(v) = α + βv is a Bayes-Nash equilibrium of this model.