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
c=r2
else
c=r3
```

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
c=r2
elseif r3/r1 > 0.665 then
c=r3
else
c=r4
```

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
repeat
inc(i)
until (r[i]/Max(r[1]..r[i-1]) > V[i]) or (i=k)
c=r[i]
```

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
```

Nitself. I have the gut feeling that in order to properly solve the case for generalk, you'll have to make some kind of assumption about the distribution ofNas well. – MvG Aug 8 '12 at 6:54