There are n points on the plane, how can one approximately find the minimal radius of a circle that covers some k out of n these points? Number n is supposed to be less then 10^4.
There is lots of information on the case k==n in Wikipedia, but I found nothing on general case.
Here's an algorithm that, given a radius r > 0 and an approximation constant c > 0, either returns a circle of radius (1+c) r enclosing at least k points or declares that there is no circle of radius r strictly enclosing at least k points. The running time is O(n (1 + k^-1 c^-2 log c^-1)), which, when used in conjunction with binary search to obtain a sufficiently coarse estimate, should be faster than tmyklebu's algorithm. (To initialize the search, it's possible in time O(n^2) to get a 2-approximation for r by looping over the points and running quickselect to find the kth closest other point.)
Partition the points by placing point (x, y) in a square bin labeled (floor(x/(2r)), floor(y/(2r))). Every circle of radius r has an interior that overlaps at most four bins. If there exists a circle of radius r enclosing at least k points, then there exist i, j such that the bins (i, j), (i, j+1), (i+1, j), (i+1, j+1) together hold at least k points.
For each of these subproblems, place each involved point (x, y) in a smaller square bin, (floor(x/w), floor(y/w)), where w = cr/(3sqrt(1/2)) is a sufficiently small width. Now prepare an O(c^-1) by O(c^-1) matrix where each entry tells how many points are contained in the corresponding bin. Convolve this matrix in two dimensions with a zero-one matrix indicating the bins completely contained in a radius-(1+c)r circle. The latter matrix might look like
01110
11111
11111
11111
01110.
Now we know for each center on the grid a number that is lowerbounded by how many points a circle of radius r would contain and upperbounded by how many points a circle of radius (1+c) r would contain.
Given a candidate radius r, you can find the maximum number of points that can be contained by a circle of radius r by taking every pair (p1, p2) of points and seeing how many points are contained by each of the two circles of radius r with p1 and p2 on the boundary.
Knowing this, you can binary search for the smallest r such that some circle of radius r contains k or more points.
p1. There are n-1 points other than p1. Bolt a radius-r circle to p1 and spin it around; each point other than p1 will enter and leave the circle at most once per revolution.
O(iterations * n^2 log n) with O(n log n) from sort - but it seems to be too slow anyway.
One thought is that you could take the average of all of the points as the center, then grow the radius until you've covered k points. Under fairly uniform distributions this would probably do a pretty good job, but would fail for "clumpy" data. For example, if the points were in two tight clusters far from each other and k was small enough to just necessitate one of them, this would fail spectacularly. If there's the possibility for this clumping, consider using a clustering algorithm to identify local clusters, and then if one of them contains enough points use the algorithm just on that cluster.
