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A company has a competition to win a car. Each contestant needs to pick a positive integer. If there’s at least one unique choice, the person who made the smallest unique choice wins the car. If there are no unique choices, the company keeps the car and there’s no repeat of the competition. It turns out that there are only three contestants, and you’re one of them. Everyone knows before picking their numbers that there are only three contestants. How should you make your choice?

Thoughts: Since there's no strategy you can adopt that the others cant, you need to aim for the situation where the other 2 pick the same number so you need to avoid them, so perversely aim high. However the other 2 can do the same as well, so do you aim lower of the high numbers, or does it make no difference?

I understand the answer is not: pick 12, but once you've gone beyond the strategy of getting the other 2 to match, do you hedge your bets somewhat by keeping it low, or do you maximise your chances of your strategy working by going insanely high (utilising exponentials etc.).

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1 seems to be the best choice, as you only lose if BOTH other people pick 1 (or, rather, if only one other person picks 1, you would lose no matter what). Pick 2 if you think both other people will pick 1. There is no reason to pick anything higher. –  Carl Nov 10 '11 at 2:19
    
So what should you do??? (ps. posted by a 11 yr old) –  user133592 Mar 6 at 18:58

3 Answers 3

Let's say that n is the highest number any player can pick. Then if you choose n, you win anytime the two other players choose the same number except n.

Now consider to choose n+1, then you win anytime the two others pick the same numbers. We observe that n+1 is better than n, and there can't be an equilibrium. Therefore, there'll be a lot high submissions by each contestant.

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Shameless Advertisement: Game Theory proposal on Area 51 that you should follow!

This is the lowest unique positive integer (LUPI) game, which is relatively well studied or sparsely studied depending on who you ask, and in which year you've asked. There appear to be some nice answers; for example, if all numbers are allowed, one symmetric mixed strategy is:

$$\text{Each player chooses } m \text{ with probability } \frac{1}{2^m}$$

For a symmetric equilibrium among the first $n=3$ natural numbers, choose $1$ with probability $2\sqrt3-3\approx46.4\%$ and $2$ and $3$ each with probability $2-\sqrt3\approx26.8\%$, according to Comments on 'Reverse Auction: The Lowest Unique Positive Integer Game (2008)

If there is "Poisson-distributed uncertainty about the number of players", then you'll need a model like that in Testing Game Theory in the Field: Swedish LUPI Lottery Games (2010), which gives some experimental and actual results, should you be so inclined.

Other references, generally dealing with endogenous entry (anyone can enter) include:

Some of which are from this nearly identical MathOverflow post on Lowest Unique Bid

After spending considerable time on what I thought was a simple question (despite having been previously forewarned in a Behavioral Game Theory class two years ago), I can't actually validate these answers, but someone on a Game Theory StackExchange might!

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I assume there is no possibility of collusion between players. Consider mixed strategies $S$ where you choose positive integer $i$ with probability $S_i$. Thus all $S_i \ge 0$ and $\sum_{i=1}^\infty S_i = 1$. There appears to be a Nash equilibrium in which all three players (independently) use the same mixed strategy, which gives positive probabilities to all positive integers. The first 9 probabilities are approximately $S_1 = .4563110597, S_2 = .2480914427, S_3 = .1348849695, S_4 = 0.07333654926, S_5 = 0.03987532390$, $S_6 = 0.02168843374, S_7 = 0.01181641450, S_8 = 0.006495476489, S_9 = 0.003750165099$. I obtained these as follows.

Suppose the other two players both choose the mixed strategy $S$, and you choose number $j$. Then the probability you win (i.e. either both choose the same number $< j$ or both choose numbers $> j$) is $Q_j = \sum_{i=1}^{j-1} S_i^2 + (1 - \sum_{i=1}^j S_i)^2$. In order for $S$ with all $S_i > 0$ to be a Nash equilibrium, no player can have an incentive to "defect", so no $Q_j$ can be greater than the probability $Q_S$ of winning if you also choose mixed strategy $S$. But $Q_S = \sum_{j=1}^\infty Q_j S_j$, so $Q_S \le \max_j Q_j$. We conclude that all $Q_j$ must be equal. So $S$ should be a solution of the infinite set of nonlinear equations $ \{ \sum_{j=1}^\infty S_j = 1, \ Q_1 = Q_2 = Q_3 = \ldots \} $. I doubt that there is a closed-form solution, but I used Maple's fsolve to get a numerical solution to a finite truncation of the system, with the result I quoted above.

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