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The question is as follow,

Alice and Bob would both like to own the same manuscript. The manuscript is worth 5 million to Alice and worth 3 million to Bob. The present owner of the manuscript proposes the following method of sale, known as a “second-price auction”. Alice and Bob will each simultaneously write down a “bid” for the manuscript. Let $b_A$ be Alice's bid, and let $b_B$ be Bob's bid. The manuscript will go to the person whose bid is highest, and that person will have to pay the other person's bid. If the bids are tied, then a fair coin will be tossed to decide who gets the manuscript, and that person will have to pay the tied bid.

Everything above is common knowledge to the players (in particular, they know each other's valuations). There are no other bidders. Negative bids are not allowed.

a) Write down each player’s payoff function in this game (payoff as a function of bids). Assume the payoff is in millions.

b) What are Alice's best responses to b_B = 2$? What are Alice's best responses to $b_B = 10?

c) Are there any equilibria in which Bob wins the manuscript? Explain very briefly.

For a)

I regard payoff function as their expected payoff:

For Alice: P(b_A \ge b_B)[5-b_B]

For Bob: P(b_B\ge b_A)[3-b_A]

For b)

In either case, the best response for alice is to bid her true value. The reason for this is that when b_B > 5$, this could make the probability of winning as small as possible; and when $b_B < 5$, this could make the probability of winning as large as possible.

Am I correct?

For c)

I do not know how to answer this one, but seems there is not any equilibrium for this case..

thanks for helping!

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    thanks for correcting them!2012-12-08

1 Answers 1

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I think, a) requires the payoff functions given actual bid values, not (yet) probabilities - or rathe with expected values only playing a role with repset to the tie-breakon coin toss. That is for Alice, the payoff is $f_A(b_A,b_B)=\begin{cases}5-b_A&b_A> b_B\\ \frac{5-b_A}2&b_A= b_B\\ 0&b_A< b_B\end{cases}$ and similarly $f_B(b_A,b_B)=\begin{cases}0&b_A> b_B\\ \frac{3-b_B}2&b_A= b_B \\3-b_B&b_A

If $b_B=2$, then $b_A=2+\epsilon$ yields $f_A(b_A,b_B)=3-\epsilon$ for Alice (but $b_B=0$ yields only $\frac32$).

If $b_B=10$, then any response $b_A\le 5$ yields $f(b_A,b_B)=0$.

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    i do not think this is the answer, but still thanks Hagen!2012-12-08