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 k
th 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.