# Generate random points on a surface of the cylinder

I want to generate random points on the surface of cylinder such that distance between the points fall in a range of 230 and 250. I used the following code to generate random points on surface of cylinder:

``````import random,math
H=300
R=20
s=random.random()
#theta = random.random()*2*math.pi
for i in range(0,300):
theta = random.random()*2*math.pi
z = random.random()*H
r=math.sqrt(s)*R
x=r*math.cos(theta)
y=r*math.sin(theta)
z=z
print 'C'  , x,y,z
``````

How can I generate random points such that they fall with in the range(on the surfaceof cylinder)?

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Distance along the surface of the cylinder, or straight-line (Euclidean)? –  NPE Apr 4 '13 at 12:28
along surface of cylinder –  user1407199 Apr 4 '13 at 12:29
Please add that to the question. –  NPE Apr 4 '13 at 12:31
is the question clear ? I am have to generate some points such that the distance between any two points is between 230 and 250 –  user1407199 Apr 4 '13 at 13:37
I believe what you are looking for is a Poisson disc sampling –  Vincent Nivoliers Apr 4 '13 at 17:39
show 8 more comments

This is not a complete solution, but an insight that should help. If you "unroll" the surface of the cylinder into a rectangle of width `w=2*pi*r` and height `h`, the task of finding distance between points is simplified. You have not explained how to measure "distance along the surface" between points on the top of the cylinder and the side- this is a slightly tricky bit of geometry.

As for computing the distance along the surface when we created an artificial "seam", just use both (x1-x2) and (w -x1+x2) - whichever gives the shorter distance is the one you want.

I do think that @VincentNivoliers' suggestion to use Poisson disk sampling is very good, but with the constraints of h=300 and r=20 you will get terrible results no matter what.

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The basic way of creating a set of random points with constraints in the positions between them, is to have a function that modulates the probability of points being placed at a certain location. this function starts out being a constant, and whenever a point is placed, forbidden areas surrounding the point are set to zero. That is difficult to do with continuous variables, but reasonably easy if you discretize your problem.

The other thing to be careful about is the being on a cylinder part. It may be easier to think of it as random points on a rectangular area that repeats periodically. This can be handled in two different ways:

1. the simplest is to take into consideration not only the rectangular tile where you are placing the points, but also its neighbouring ones. Whenever you place a point in your main tile, you also place one in the neighboring ones and compute their effect on the probability function inside your tile.

2. A more sophisticated approach considers the probability function then convolution of a kernel that encodes forbidden areas, with a sum of delta functions, corresponding to the points already placed. If this is computed using FFTs, the periodicity is anatural by product.

The first approach can be coded as follows:

``````from __future__ import division
import numpy as np

r, h = 20, 300
w = 2*np.pi*r
int_w = int(np.rint(w))
mult = 10
pdf = np.ones((h*mult, int_w*mult), np.bool)
points = []
min_d, max_d = 230, 250

available_locs = pdf.sum()
while available_locs:
new_idx = np.random.randint(available_locs)
new_idx = np.nonzero(pdf.ravel())[0][new_idx]
new_point = np.array(np.unravel_index(new_idx, pdf.shape))
points += [new_point]
if max_d is not None:
else:
for p in [new_point - [0, int_w*mult], new_point +[0, int_w*mult],
new_point]:
rows = ((np.arange(pdf.shape[0]) - p[0]) / mult)**2
cols = ((np.arange(pdf.shape[1]) - p[1]) * 2*np.pi*r/int_w/mult)**2
dist2 = rows[:, None] + cols[None, :]
min_mask &= dist2 > min_d*min_d
if max_d is not None:
max_mask |= dist2 < max_d*max_d
available_locs = pdf.sum()
points = np.array(points) / [mult, mult*int_w/(2*np.pi*r)]
``````

If you run it with your values, the output is usually just one or two points, as the large minimum distance forbids all others. but if you run it with more reasonable values, e.g.

``````min_d, max_d = 50, 200
``````

Here's how the probability function looks after placing each of the first 5 points:

Note that the points are returned as pairs of coordinates, the first being the height, the second the distance along the cylinder's circumference.

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