I guess the integer coordinate constraint simplifies the problem notably. This looks like O(n) to me:

-Make a dictionary of all integer points in space and set the entries to 0.

-For each datapoint find the integer points that are within radius 3, and add 1 to the corresponding entries of the dictionary. The reason for doing this is that the set of points that can be the centers of a circle in which that particular datapoint is inside is the integer restriction of a circle with the same radius around that datapoint. The search could be done over all points lying on a square of length 6 (thought not all points need to be evaluated explicitly as these inside the inscribed hypercube are inside for sure).

-Return the integer point corresponding to the maximum value of the dictionary, ie the center for which most datapoints are inside the circle.

**Edit:** I guess some code is better than explanations. This is working python with numpy and matplotlib. Shouldn't be too difficult to read:

```
# -*- coding: utf-8 -*-
"""
Created on Mon Mar 11 19:22:12 2013
@author: Zah
"""
from __future__ import division
import numpy as np
import numpy.random
import matplotlib.pyplot as plt
from collections import defaultdict
import timeit
def make_points(n):
"""Generates n random points"""
return np.random.uniform(0,30,(n,2))
def find_centers(point, r):
"""Given 1 point, find all possible integer centers searching in a square
around that point. Note that this method can be imporved."""
posx, posy = point
centers = ((x,y)
for x in xrange(int(np.ceil(posx - r)), int(np.floor(posx + r)) + 1)
for y in xrange(int(np.ceil(posy - r)), int(np.floor(posy + r)) + 1)
if (x-posx)**2 + (y-posy)**2 < r*r)
return centers
def find_circle(n, r=3.):
"""Find the best center"""
points = make_points(n)
d = defaultdict(int)
for point in points:
for center in find_centers(point, r):
d[center] += 1
return max(d , key = lambda x: d[x]), points
def make_results():
"""Green circle is the best center. Red crosses are posible centers for some
random point as an example"""
r = 3
center, points = find_circle(100)
xv,yv = points.transpose()
fig = plt.figure()
ax = fig.add_subplot(111)
ax.set_aspect(1)
ax.scatter(xv,yv)
ax.add_artist(plt.Circle(center, r, facecolor = 'g', alpha = .5, zorder = 0))
centersx, centersy = np.array(list(find_centers(points[0], r))).transpose()
plt.scatter(centersx, centersy,c = 'r', marker = '+')
ax.add_artist(plt.Circle(points[0], r, facecolor = 'r', alpha = .25, zorder = 0))
plt.show()
if __name__ == "__main__":
make_results()
```

Results:
Green circle is the best one, and the red stuff demonstrates how centers are picked for some random point.

```
In [70]: %timeit find_circle(1000)
1 loops, best of 3: 1.76 s per loop
In [71]: %timeit find_circle(2000)
1 loops, best of 3: 3.51 s per loop
In [72]: %timeit find_circle(3000)
1 loops, best of 3: 5.3 s per loop
In [73]: %timeit find_circle(4000)
1 loops, best of 3: 7.03 s per loop
```

In my really slow machine. Behaviour is clearly linear.