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)
active_list.append((x0,y0))
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
active_list.append(p)
break
else:
del active_list[i]
return X
X = generate_samples(2500, 200, 10)
s = np.where(X>0)
plt.plot(s[0],s[1],'.')
```

And the results: