Since you're using great-circle distances, there are a couple possibilities that provide some quality guarantee: approximation schemes for Euclidean graphs, and integer programming. The former is in theory more scalable, but the latter gives exact optima and is a lot easier to implement assuming that a solver is available. (Of course, you could always do something ad hoc.) Since you have so few locations, that's the one I'll describe.

I'll explain integer programs briefly by formulating your problem as one.

```
maximize profit1 * x1 + profit2 * x2 + ... + profit250 * x250
subject to
x1 + x2 + ... + x250 = 5 (select exactly 5 localities)
for every pair of localities {i, j} less than 5 miles from each other,
xi + xj <= 1
x1, x2, ..., x250 in {0, 1}
```

The meaning of variable `xi`

is that it's 1 if locality `i`

is selected and 0 if locality `i`

is not selected.

You'll need to write a small subroutine to communicate this program to your favorite solver in its preferred format. To find a solver, search for "MIP solver"; there are free and commercial offerings with bindings to a variety of languages. Try to get one that supports clique cuts (I know the commercial CPLEX and the free GLPK do). If it doesn't, that's OK; you can implement Bron–Kerbosch yourself to generate constraints of the form

```
xa + xb + ... + xz <= 1
```

where `a, b, ..., z`

are localities each within 5 miles of one another.

`maximize expected profit such that minimum distance between each locality is 5 miles`

you man you want 5 selected localities whose sum of profits is maximized over the set AND where the distance between any two localities within these 5 is greater than or equal to 5 miles? – lurker May 22 '13 at 15:42n)) which relatively simple pair-constraints. A "Greedy Pairs" algorithm O(kn^2) would probably beveryclose to optimal. – RBarryYoung May 22 '13 at 15:46