You can apply essentially the same idea as the algorithm I described in this question.
Let's look for the center of the final subset. It must minimize the maximum distance to each of the sets. As usual, the distance of a point to a set is defined as the minimum distance between the point and an element of the set.
For each set
i, the function
fi describing the distance to the set is piecewise linear. If a,b are two consecutive numbers, the relations
fi(a) = 0, fi((a+b)/2) = (b-a)/2, fi(b) = 0 let us build a description of all the
fi in linear time.
But we can also compute the maximum of two piecewise functions
fj in linear time, by considering the consecutive intervals [a,b] where they are linear: either the result is linear, or it is piecewise linear by adding the unique intersection point of the functions to the partition. Since the slopes of our functions are always +1 or -1, the intersection point is a half-integer so it can be represented exactly in floating-point (or fixed-point) arithmetic.
A convexity argument shows that the maximum
g of all the
fi can only have at most twice as many points as the
fi, so we don't have to worry about the maximum having a number of points that would be exponential in the number of sets.
So we just:
- Compute the piecewise linear distance function
i = 1..p.
- Compute the maximum
g of all the
fi by repeatedly computing the maximum.
- The location of any minimum point of
g is the desired center.
- For each set, pick the closest point to the center.
- The width of the set of points we picked is exactly the minimum of
Complexity is O(N) if the number of sets is bounded, or O(N p) if the number of sets p is variable. By being smart about how you compute the maximum (divide-and-conquer), I think you can even reduce it to O(N log p).