Since this is an interview question, here is my shot at a solution. *(As dcn points out below, this is not guaranteed to return the optimal solution, though it should still be a decent heuristic. Good catch, dcn!)*

- Create a set S
_{p} with a single point P.
- Compute the distance between every point in S
_{p} and every point outside of it, then add the point with the smallest max distance to S_{p}.
- Repeat 2. until S
_{p} has k points.
- Repeat 1-3 using each point once as the initial P. Take the S
_{p} which has the smallest max distance.

There are O(k) points in S_{p}, and O(n) points outside of it, so finding the point with the smallest max distance is O(nk). We repeat this k times, then repeat the *whole* procedure n times, for an overall complexity of **O(n**^{2}k^{2}).

We can improve on this by caching the max distance between *any* point in S_{p} and each point outside of S_{p}. If `maxDistanceFromPointInS[pointOutsideS]`

is, say, an O(1) hash-table containing the current max distance between every point `pointOutsideS`

and some point inside S_{p}, then every time we add a new point `newPoint`

, we set `maxDistanceFromPointInS[p] = Max(maxDistanceFromPointInS[p], distance(newPoint, p))`

for all points `p`

outside of S_{p}. Then finding the smallest max distance is O(n), adding a point to S_{p} is O(n). Repeating this k times gives us O((n+n)k) = O(nk). Finally, we repeat the *whole* procedure n times, for an overall complexity of **O(n**^{2}k).

We could improve finding the smallest max distance to O(1) using a heap, but that would not change the overall complexity.

By the way, it took an hour to write this all up - there's no way I could have done this in an interview.