# Uniformly distribute x points inside a circle

I would like to uniformly distribute a predetermined set of points within a circle. By uniform distribution, I mean they should all be equally distanced from each other (hence a random approach won't work). I tried a hexagonal approach, but I had problems consistently reaching the outermost radius.

My current approach is a nested for loop where each outer iteration reduces the radius & number of points, and each inner loop evenly drops points on the new radius. Essentially, it's a bunch of nested circles. Unfortunately, it's far from even. Any tips on how to do this correctly? • Take a look at low-discrepenacy sequences. Feb 17, 2015 at 17:32
• What do you want to happen on the boundary, do the points have to be uniformly spaced around the boundary of the circle? Otherwise you could take a uniform grid (triangular, hexagonal, or square) and keep from it only the points within the circle.
– user3717023
Feb 17, 2015 at 19:51
• RobertDodier, thanks, unfortunately even subrandom numbers don't produce favorable results as the chance of 2 points landing closely next to each other is still relatively high. FamousBlueRaincoat, ideally, yes for this case I would like the outermost points to be uniformly spaced around the edge. Feb 17, 2015 at 21:52
• Sunflower seed arrangement uses golden ratio for angle increments and square root for radius increment. The result looks pretty good, but the outer edge isn't perfectly circular.
– user3717023
Feb 17, 2015 at 21:59
• Equally spaced points form an hexagonal lattice and can't lie on a circular boundary (except N=7). What you are asking is impossible, you must relax some condition.
– user1196549
Feb 18, 2015 at 14:00

The goals of having a uniform distribution within the area and a uniform distribution on the boundary conflict; any solution will be a compromise between the two. I augmented the sunflower seed arrangement with an additional parameter `alpha` that indicates how much one cares about the evenness of boundary.

`alpha=0` gives the typical sunflower arrangement, with jagged boundary: With `alpha=2` the boundary is smoother: (Increasing alpha further is problematic: Too many points end up on the boundary).

The algorithm places `n` points, of which the `k`th point is put at distance `sqrt(k-1/2)` from the boundary (index begins with `k=1`), and with polar angle `2*pi*k/phi^2` where `phi` is the golden ratio. Exception: the last `alpha*sqrt(n)` points are placed on the outer boundary of the circle, and the polar radius of other points is scaled to account for that. This computation of the polar radius is done in the function `radius`.

It is coded in MATLAB.

``````function sunflower(n, alpha)   %  example: n=500, alpha=2
clf
hold on
b = round(alpha*sqrt(n));      % number of boundary points
phi = (sqrt(5)+1)/2;           % golden ratio
for k=1:n
theta = 2*pi*k/phi^2;
plot(r*cos(theta), r*sin(theta), 'r*');
end
end

if k>n-b
r = 1;            % put on the boundary
else
r = sqrt(k-1/2)/sqrt(n-(b+1)/2);     % apply square root
end
end
``````
• This works great. For future readers,I made this geodesic by turning theta into a bearing so I could pass it into a destination function. I did that with the following line `theta = k * (720 - 360 * phi)`. It looks correct, but if I'm in error please correct me. Feb 18, 2015 at 17:13
• I think 720 is redundant; when multiplied by k, it's just 2*k full turns. You could use `theta = -k*360*phi` instead; or `theta = k*360*phi` since the minus sign is just mirror reflection.
– user3717023
Feb 18, 2015 at 18:03
• Right again! Looks like I need a refresher in geometry :-/. Feb 18, 2015 at 22:18
• Any idea how to take this into 3D? Plotting all points within a sphere? May 21, 2020 at 5:32

Might as well tag on my Python translation.

``````from math import sqrt, sin, cos, pi
phi = (1 + sqrt(5)) / 2  # golden ratio

def sunflower(n, alpha=0, geodesic=False):
points = []
angle_stride = 360 * phi if geodesic else 2 * pi / phi ** 2
b = round(alpha * sqrt(n))  # number of boundary points
for k in range(1, n + 1):
theta = k * angle_stride
points.append((r * cos(theta), r * sin(theta)))
return points

if k > n - b:
return 1.0
else:
return sqrt(k - 0.5) / sqrt(n - (b + 1) / 2)

# example
if __name__ == '__main__':
import matplotlib.pyplot as plt
fig, ax = plt.subplots()
points = sunflower(500, alpha=2, geodesic=False)
xs = [point for point in points]
ys = [point for point in points]
ax.scatter(xs, ys)
ax.set_aspect('equal') # display as square plot with equal axes
plt.show()
``````

Stumbled across this question and the answer above (so all cred to user3717023 & Matt).
Just adding my translation into R here, in case someone else needed that :)

``````library(tibble)
library(dplyr)
library(ggplot2)

sunflower <- function(n, alpha = 2, geometry = c('planar','geodesic')) {
b <- round(alpha*sqrt(n))  # number of boundary points
phi <- (sqrt(5)+1)/2  # golden ratio

theta <- 1:n * ifelse(geometry == 'geodesic', 360*phi, 2*pi/phi^2)

tibble(
x = r*cos(theta),
y = r*sin(theta)
)
}

ifelse(
k > n-b,
1,
sqrt(k-1/2)/sqrt(n-(b+1)/2)
)
}

# example:
sunflower(500, 2, 'planar') %>%
ggplot(aes(x,y)) +
geom_point()
``````

Building on top of @OlivelsAWord , here is a Python implementation using numpy:

``````import numpy as np
import matplotlib.pyplot as plt

def sunflower(n: int, alpha: float) -> np.ndarray:
# Number of points respectively on the boundary and inside the cirlce.
n_exterior = np.round(alpha * np.sqrt(n)).astype(int)
n_interior = n - n_exterior

# Ensure there are still some points in the inside...
if n_interior < 1:
raise RuntimeError(f"Parameter 'alpha' is too large ({alpha}), all "
f"points would end-up on the boundary.")
# Generate the angles. The factor k_theta corresponds to 2*pi/phi^2.
k_theta = np.pi * (3 - np.sqrt(5))
angles = np.linspace(k_theta, k_theta * n, n)

r_interior = np.sqrt(np.linspace(0, 1, n_interior))
r_exterior = np.ones((n_exterior,))
r = np.concatenate((r_interior, r_exterior))

# Return Cartesian coordinates from polar ones.
return r * np.stack((np.cos(angles), np.sin(angles)))

# NOTE: say the returned array is called s. The layout is such that s[0,:]
# contains X values and s[1,:] contains Y values. Change the above to
#   return r.reshape(n, 1) * np.stack((np.cos(angles), np.sin(angles)), axis=1)
# if you want s[:,0] and s[:,1] to contain X and Y values instead.

if __name__ == '__main__':
fig, ax = plt.subplots()

# Let's plot three sunflowers with different values of alpha!
for alpha in (0, 1, 2):
s = sunflower(500, alpha)
# NOTE: the 'alpha=0.5' parameter is to control transparency, it does
# not have anything to do with the alpha used in 'sunflower' ;)
ax.scatter(s, s, alpha=0.5, label=f"alpha={alpha}")

# Display as square plot with equal axes and add a legend. Then show the result :)
ax.set_aspect('equal')
ax.legend()
plt.show()

`````` ``````int n = 2000; // count of nodes
Float alpha = 2.; // constant that can be adjusted to vary the geometry of points at the boundary
ArrayList<PVector> vertices = new ArrayList<PVector>();
Float scaleFactor = 200.; // scale points beyond their 0.0-1.0 range for visualisation;

void setup() {
size(500, 500);
// Test
vertices = sunflower(n, alpha);
displayTest(vertices, scaleFactor);
}

ArrayList<PVector> sunflower(int n, Float alpha) {
Double phi = (1 + Math.sqrt(5)) / 2; // golden ratio
Double angle = 2 * PI / Math.pow(phi, 2); // value used to calculate theta for each point
ArrayList<PVector> points = new ArrayList<PVector>();
Long b = Math.round(alpha*Math.sqrt(n)); // number of boundary points
Float theta, r, x, y;

for (int i = 1; i < n + 1; i++) {
theta = i * angle.floatValue();
x = r * cos(theta);
y = r * sin(theta);
PVector p = new PVector(x, y);
}
return points;
}

Float radius(int k, int n, Float b) {
if (k > n - b) {
return 1.0;
} else {
Double r = Math.sqrt(k - 0.5) / Math.sqrt(n - (b+1) / 2);
return r.floatValue();
}
}

void displayTest(ArrayList<PVector> points, Float size) {
for (int i = 0; i < points.size(); i++) {
Float x = size * points.get(i).x;
Float y = size * points.get(i).y;
pushMatrix();
translate(width / 2, height / 2);
ellipse(x, y, 5, 5);
popMatrix();
}
}
``````

Here's my Unity implementation.

``````Vector2[] Sunflower(int n, float alpha = 0, bool geodesic = false){
float phi = (1 + Mathf.Sqrt(5)) / 2;//golden ratio
float angle_stride = 360 * phi;
float radius(float k, float n, float b)
{
return k > n - b ? 1 : Mathf.Sqrt(k - 0.5f) / Mathf.Sqrt(n - (b + 1) / 2);
}

int b = (int)(alpha * Mathf.Sqrt(n));  //# number of boundary points

List<Vector2>points = new List<Vector2>();
for (int k = 0; k < n; k++)
{
float r = radius(k, n, b);
float theta = geodesic ? k * 360 * phi : k * angle_stride;
float x = !float.IsNaN(r * Mathf.Cos(theta)) ? r * Mathf.Cos(theta) : 0;
float y = !float.IsNaN(r * Mathf.Sin(theta)) ? r * Mathf.Sin(theta) : 0;