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I want to generate a bunch (x, y) coordinates from 0 to 2500 that excludes points that are within 200 of each other without recursion.

Right now I have it check through a list of all previous values to see if any are far enough from all the others. This is really inefficient and if I need to generate a large number of points it takes forever.

So how would I go about doing this?

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One way would be to populate a list with all available points. Then pick a random element of your list and remove all points that are too close to it. This would be pretty expensive memory-wise though. One way to implement this would be a 2500 x 2500 array of 0-1 which represent valid or invalid. Generate x and y, if points[x][y] == 0 then set it to one and set everything in range x-100 to x+100 and y-100 to y+100. Removing points in a square would be easier than points in a 200 radius circle, if you can get away with that. –  hankd Oct 29 '13 at 20:35
Are these points random? How random? –  iamnotmaynard Oct 29 '13 at 20:46
Draw a grid, placing the origin at random. Then take for points the centre of each square. Done. –  Colonel Panic Oct 29 '13 at 21:14
@ColonelPanic That wouldn't be a very random distribution of points. Every points would have 4 points equidistant to it. –  hankd Oct 29 '13 at 21:16

4 Answers 4

This is a variant on Hank Ditton's suggestion that should be more efficient time- and memory-wise, especially if you're selecting relatively few points out of all possible points. The idea is that, whenever a new point is generated, everything within 200 units of it is added to a set of points to exclude, against which all freshly-generated points are checked.

import random

radius = 200
rangeX = (0, 2500)
rangeY = (0, 2500)
qty = 100  # or however many points you want

# Generate a set of all points within 200 of the origin, to be used as offsets later
# There's probably a more efficient way to do this.
deltas = set()
for x in range(-radius, radius+1):
    for y in range(-radius, radius+1):
        if x*x + y*y <= radius*radius:

randPoints = []
excluded = set()
i = 0
while i<qty:
    x = random.randrange(*rangeX)
    y = random.randrange(*rangeY)
    if (x,y) in excluded: continue
    i += 1
    excluded.update((x+dx, y+dy) for (dx,dy) in deltas)
print randPoints
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Nice! It is certainly more efficient space-wise, but is it time-wise? In both algorithms we are generating a point, setting the same amount of points as excluded, and possibly throwing away the point if it is not valid. –  hankd Oct 29 '13 at 21:15
This didn't seem to work. Many of the points generated are on top of eachother. –  user2901745 Oct 30 '13 at 1:02
@user2901745: Really? The output looks as expected to me. Do you mean the code is generating duplicate points in a single run? Could you give an example? –  jwodder Oct 30 '13 at 1:06
Yeah, you can see here that the points are overlapping. I'm using the generated list to paste random characters around this image (although, I'm having trouble getting this font to work, but that's a different problem). They're not duplicate, but they are within 200px of eachother. Here's two points that I found that were both generated in the same call: (1975, 2169), (1917, 2191) –  user2901745 Oct 30 '13 at 1:42
@user2901745: Ah, I see what I did wrong. I forgot to square radius in line 13, making the effective radius actually about 14.1. –  jwodder Oct 30 '13 at 2:13

I would overgenerate the points, target_N < input_N, and filter them using a KDTree. For example:

import numpy as np
from scipy.spatial import KDTree
N   = 20
pts = 2500*np.random.random((N,2))

tree = KDTree(pts)
print tree.sparse_distance_matrix(tree, 200)

Would give me points that are "close" to each other. From here it should be simple to apply any filter:

  (11, 0)   60.843426339
  (0, 11)   60.843426339
  (1, 3)    177.853472309
  (3, 1)    177.853472309
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Some options:

  • Use your algorithm but implement it with a kd-tree that would speed up nearest neighbours look-up
  • Build a regular grid over the [0, 2500]^2 square and 'shake' all points randomly with a bi-dimensional normal distribution centered on each intersection in the grid
  • Draw a larger number of random points then apply a k-means algorithm and only keep the centroids. They will be far away from one another and the algorithm, though iterative, could converge more quickly than your algorithm.
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This has been answered, but it's very tangentially related to my work so I took a stab at it. I implemented the algorithm described in this note which I found linked from this blog post. Unfortunately it's not faster than the other proposed methods, but I'm sure there are optimizations to be made.

import numpy as np
import matplotlib.pyplot as plt

def lonely(p,X,r):
    m = size(X,1)
    x0,y0 = p
    x = y = np.arange(-r,r)
    x = x + x0
    y = y + y0

    u,v = np.meshgrid(x,y)

    u[u < 0] = 0
    u[u >= m] = m-1
    v[v < 0] = 0
    v[v >= m] = m-1

    return not any(X[u[:],v[:]] > 0)

def generate_samples(m=2500,r=200,k=30):
    # m = extent of sample domain
    # r = minimum distance between points
    # k = samples before rejection
    active_list = []

    # step 0 - initialize n-d background grid
    X = np.ones((m,m))*-1

    # step 1 - select initial sample
    x0,y0 = np.random.randint(0,m), np.random.randint(0,m)
    X[active_list[0]] = 1

    # step 2 - iterate over active list
    while active_list:
        i = np.random.randint(0,len(active_list))
        rad = np.random.rand(k)*r+r
        theta = np.random.rand(k)*2*pi

        # get a list of random candidates within [r,2r] from the active point
        candidates = np.round((rad*cos(theta)+active_list[i][0],rad*sin(theta)+active_list[i][3])).astype(integer).T

        # trim the list based on boundaries of the array
        candidates = [(x,y) for x,y in candidates if x >= 0 and y >= 0 and x < m and y < m]

        for p in candidates:
            if X[p] < 0 and lonely(p,X,r):
                X[p] = 1
            del active_list[i]

    return X

X = generate_samples(2500, 200, 10)
s = np.where(X>0)

And the results:

Resulting sample pattern

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