| Sorry, I wasn't specific enough. Let's define 'best strategy' here
as that strategy which has the highest expected value.
The first part of the problem (where maximum number of rolls is
known) should be quite easy. When the maximum number of rolls is
unknown, however, I'm not sure if the problem is easy or hard.
The existence of a best strategy here may be a good question.
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| Let's try to make the question more definite. Suppose you always
have the choice of stopping with your current roll, or asking for
another roll. If you ask for another roll, it's probability p that
you get it, and probability (1-p) that you don't. What's best to
choose if your current roll is 1? 2? 3? 4? 5? 6?
I think this is another nice problem for non-regular contributors.
John
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| Spoiler follows.
�
For an M-sized die with sides numbered 1 thru M, and a 'current roll'
of n, the expectation is maximized by asking for another roll if n=1,
or if
M 2n-M-1
p > --- --------.
n n-1
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| For one roll, each of 1,...,6 is equally likely, and the
expected value is E1=3+1/2. For two rolls, roll again if
your first roll is less than E1. Your expected value is
1/6(4+5+6+3*E1)
because you stop with 4,5,6 and play the one roll game on
the other three initial rolls. So E2=4+1/4. For the three
roll game, stop at a 5 or 6 and otherwise roll again
[playing the two roll game.] E3 = 4+2/3. Continuing in
this manner you get E4=4+17/18 and E5=5+7/54. So the
strategy this leads to is:
After you roll,
if you have 0 rolls left, stop
if you have 1 roll left, stop at 4,5,6
if you have 2,3,4 rolls left, stop at 5,6
if you have 5 or more rolls left, stop at 6
otherwise, roll again.
Dan
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