I have a collection of n point sets, where each point set contains up to m points.
I want to select one point from each point set, such that the resulting selection of points is as close together as possible. (where "closeness" has a reasonable definition, like the sum of squared distances from the centroid of the selected set of points.)
For example, the input collection could be:
Point Set A: [(2, 1), (1, 2), (6, 5)] Point Set B: [(1, 1), (7, 3)] Point Set C: [(3, 7), (5, 3)]
I want to select the three points, one from each point set, where the points are closest together. In this example, the three points at the bottom-left are closest together, but they do not include a point from C. The solution here would be the points on the right: (6, 5), (7, 3), and (5, 3). These are clustered around their centroid at (6, 3⅔).
The brute-force algorithm tries every possible combination of points from the collection and keeps track of the minimum value of the "closeness" function (i.e., an O(m^n) algorithm), but I'm wondering if there's a more efficient way that scales for large values of n and m -- if not in the worst case, then at least for most inputs.
Update: The points will have real values as coordinates; integers are used above to simplify the example.