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Consider a hidden set of k random numbers {r1,r2...rk} chosen with uniform probability distribution from the range [0..N], where N is unknown to me. In each time interval, the number ri is revealed to me and I have the choice of either choosing ri as my final number c, if I haven't already made a choice for c, or moving on to the next time interval. When ri is revealed to me I can no longer choose any of r1,r2..r(i-1). If I haven't chosen a number by the time rk is revealed then, by default, that becomes c.

I want to optimise c, in the sense maximizing its expected value.

If N was known then the answer is obvious. Similarly, if k is large then I can use the early values of ri to estimate N.

Progress so far:

if k = 1 then there is no choice. By default c=r1. The expected value of c is N/2.

if k = 2 then all choice algorithms are identical with expected value N/2.

If k = 3 then the best algorithm is

if r2/r1 >= 0.75 then 

The expected value of c is approximately 0.58N.

If k = 4 then the best I have come up with is

if r2/r1 > 0.920 then
elseif r3/r1 > 0.665 then

The expected value of c is approximately 0.64N. I believe I should be able to do a little better by 'using' both the values of r1 and r2 in choosing if to accept r3 as my chosen value but an analytical solution escapes me.

Can anyone provide a better algorithm for k=4 and/or k=5?

Notes re Secretary problem: In all versions of the SP i can find, you onl;y have information on the relative rank of candidates to those that have already appeared. But in this problem you have a value for each candidate (of course from an unknown range [0..N]) and by utilising the ratio of values you can do better. For example, the SP solution to the k=3 problem (choose p2 if p2 > p1 else choose p3) has an expected return of o.5833N, whereas my solution (choose p2 if p2/p1 > 0.75 else choose p3) has an expected return of 0.5937.

My best return so far for the problem for any k is:

 i = 0    
 until (r[i]/Max(r[1]..r[i-1]) > V[i]) or (i=k)

where for any chosen k, v[i] (or call it v[k,i] if you prefer) is a pre-chosen array of real values. The standard solutions to the secretary problem uses only values of inf and 1 in V V=[inf,...inf,1,...,1], whereas I can do better (at least for small k) by using reals in V. But I believe my solution is still sub-optimal as I utilize only the value of Max(r1..ri), whereas there must be 'hidden' information in the distribution of r1..ri values at each decision point.

Best solutions to date:

k = 3 : v = [inf,0.75]          : cexp = 0.58N
k = 4 : v = [inf,0.92,0.66]     : cexp = 0.665N
k = 5 : v = [inf,inf,0.82,0.63] : cexp = 0.6683N
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Do you have any information about the probability distribution of N itself. I have the gut feeling that in order to properly solve the case for general k, you'll have to make some kind of assumption about the distribution of N as well. – MvG Aug 8 '12 at 6:54
In general I want a solution where N is completely unknown. – Penguino Aug 8 '12 at 21:14
up vote 1 down vote accepted

There's probably a good reason for why the best solutions involve only comparing ri to Max(r1, r2, ..., ri): the German Tank Problem.

Suppose you've just seen rk-1, the second-to-last number. Consider what your decision at that point is. You can either take rk-1 or wait to see the yet unrevealed rk. When should you choose rk-1? When you think that rk-1 is greater than the expected value of rk = N/2. But how can you estimate the expected value of rk if you don't know N? Well, what you would probably do is estimate N. And how do you do that? You use one of the solutions to the German Tank Problem which relies only on the maximum (and count) of the observed values.

Working out the cases for ri where i < k-1 is less straightforward. For example, when you're looking at rk-2, you need to figure out what you'd do given that you have two more numbers to see and (potentially) one more choice to make. But, I suspect that in each case, the key thing you're doing is making some estimate of N, which involves only the maximum and count of the observed values so far.

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Thanks, that reference was exactly what I wanted. – Penguino Aug 9 '12 at 22:58

It is one of many modifications of 'Secretary problem' in optimal stopping theory. I don't have ready answer on your specyfic problem, but I highly recommend to read about this 'Secretary problem'. There is a lot papers about it and I sure you will find something for this.

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Note that you can do better than N/2 for k=2:

  • take a guess at N/2 and call it m.
  • if r1 > m accept it as c, else reject and choose r2 as c.

Here is the expectation of this strategy.

  • if m ≥ N, then it always reject r1 and accept r2, the expected value of c is thus N/2.
  • if m < N, then it accepts:
    • r1 with probability (N-m)/N
    • r2 with remaining probability probability m/N

In the second case the expectation of r1 is Σ_{m<i≤N} i / (N-m) > N/2, while the expectation of r2 is N/2. In this second case the expectation of the overall strategy is greater than N/2.

This strategy is better if you get a good guess of N/2, but the cute fact is that you can't get wrong: even if you're way off, the strategy at least yields N/2 expectation.

share|improve this answer
I hadn't considered this, but doesn't this boil down to "pick a number smaller than the number I am thinking of". – Penguino Aug 8 '12 at 21:23

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