# Choosing subsets of a set such that the subsets satisfy a global constraint

We have a set of items I = {i_1, i_2, ..., i_n}. Each of these items has what we call a p value, which is some real number. We want to choose a subset of I, call it I', of size m (for some m with 1 <= m <= n) such that the average of the p values of the items in I' falls within some specified range, [p_l, p_u]. (For example, we might require an average p value between 0.70 and 0.74.) Moreover, we want to do this efficiently.

We hope to do this in O(n) time, but any polynomial time algorithm is good enough. We certainly do not want to just try every possible subset of I of size m and then check whether it satisfies the average p-value constraint.

Finally, we will be doing this repeatedly and we want the subsets chosen to be a uniformly random distribution over all the possible such subsets.

Is there a way of doing this?

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A polynomial time algorithm for this seems unlikely. This problem is likely equivalent to the general Constrained Subset Selection Problem, which is NP. If your input values are closely clustered around some pivot, and have a normal distribution, you may be able to use a backtracking algorithm to select a subset that meets the requirements. However, ensuring you get a uniform random distribution over all members of l will be challenging. You may have better luck asking for help on mathoverflow.com. –  LBushkin Aug 24 '10 at 16:41
Thanks for your comment. I tend to think the problem is intractable also. I might ask on mathoverflow.com, but so far I've found Stack Overflow to be much more helpful even with theoretical questions like this. –  Paul Reiners Aug 24 '10 at 17:15