Generate random locations within a triangular domain

I want to generate `x` and `y` having a uniform distribution and limited by `[xmin,xmax]` and `[ymin,ymax]`

The points (x,y) should be inside a triangle.

How can I solve such a problem?

• The requirements here seem underspecified (and possibly contradictory): if `x` and `y` are independent and each is uniformly distributed on an interval, they'll cover a rectangle rather than a triangle. How is this triangle specified, and what's its relation to the range `[xmin, xmax]` and `[ymin, ymax]`? – Mark Dickinson Nov 21 '17 at 16:15
• Don’t just tell us what you want (especially underspecified). What have you tried? What’s gone wrong? Where are you stuck? – Daniel H Nov 21 '17 at 18:25
• We probably all guessed that `min, max` relates to the triangle coordinates. But looking at her other question, I am afraid, we won't get any feedback. – Mr. T Nov 21 '17 at 19:36
• – Bill Bell Nov 22 '17 at 4:48

Here's some code that generates points uniformly on an arbitrary triangle in the plane.

``````import random

def point_on_triangle(pt1, pt2, pt3):
"""
Random point on the triangle with vertices pt1, pt2 and pt3.
"""
s, t = sorted([random.random(), random.random()])
return (s * pt1[0] + (t-s)*pt2[0] + (1-t)*pt3[0],
s * pt1[1] + (t-s)*pt2[1] + (1-t)*pt3[1])
``````

The idea is to compute a weighted average of the three vertices, with the weights given by a random break of the unit interval `[0, 1]` into three pieces (uniformly over all such breaks).

Here's an example usage that generates 10000 points in a triangle:

``````pt1 = (1, 1)
pt2 = (2, 4)
pt3 = (5, 2)
points = [point_on_triangle(pt1, pt2, pt3) for _ in range(10000)]
``````

And a plot obtained from the above, demonstrating the uniformity. The plot was generated by this code:

``````import matplotlib.pyplot as plt
x, y = zip(*points)
plt.scatter(x, y, s=0.1)
plt.show()
``````

Here's the image:

And since you tagged the question with the "numpy" tag, here's a NumPy version that generates multiple samples at once. Note that it uses the matrix multiplication operator `@`, introduced in Python 3.5 and supported in NumPy >= 1.10. You'll need to replace that with a call to `np.dot` on older Python or NumPy versions.

``````import numpy as np

def points_on_triangle(v, n):
"""
Give n random points uniformly on a triangle.

The vertices of the triangle are given by the shape
(2, 3) array *v*: one vertex per row.
"""
x = np.sort(np.random.rand(2, n), axis=0)
return np.column_stack([x[0], x[1]-x[0], 1.0-x[1]]) @ v

# Example usage
v = np.array([(1, 1), (2, 4), (5, 2)])
points = points_on_triangle(v, 10000)
``````

Uniform on the triangle?

``````import numpy as np

N = 10 # number of points to create in one go

rvs = np.random.random((N, 2)) # uniform on the unit square
# Now use the fact that the unit square is tiled by the two triangles
# 0 <= y <= x <= 1 and 0 <= x < y <= 1
# which are mapped onto each other (except for the diagonal which has
# probability 0) by swapping x and y.
# We use this map to send all points of the square to the same of the
# two triangles. Because the map preserves areas this will yield
# uniformly distributed points.
rvs = np.where(rvs[:, 0, None]>rvs[:, 1, None], rvs, rvs[:, ::-1])

Finally, transform the coordinates
xmin, ymin, xmax, ymax = -0.1, 1.1, 2.0, 3.3
rvs = np.array((ymin, xmin)) + rvs*(ymax-ymin, xmax-xmin)
``````

Uniform marginals? The simplest solution would be to uniformly concentrate the mass on the line (ymin, xmin) - (ymax, xmax)

``````rvs = np.random.random((N,))
rvs = np.c_[ymin + (ymax-ymin)*rvs, xmin + (xmax-xmin)*rvs]
``````

but that is not very interesting, is it?

Ok, time to add another version, I guess. There is known algorithm to sample uniformly in triangle, see paper, chapter 4.2 for details.

Python code:

``````import math
import random

import matplotlib.pyplot as plt

def trisample(A, B, C):
"""
Given three vertices A, B, C,
sample point uniformly in the triangle
"""
r1 = random.random()
r2 = random.random()

s1 = math.sqrt(r1)

x = A[0] * (1.0 - s1) + B[0] * (1.0 - r2) * s1 + C[0] * r2 * s1
y = A[1] * (1.0 - s1) + B[1] * (1.0 - r2) * s1 + C[1] * r2 * s1

return (x, y)

random.seed(312345)
A = (1, 1)
B = (2, 4)
C = (5, 2)
points = [trisample(A, B, C) for _ in range(10000)]

xx, yy = zip(*points)
plt.scatter(xx, yy, s=0.2)
plt.show()
``````

And result looks like

Step (1): Generate a coordinate with a random number `xr` in `[xmin, xmax]` and `yr` in `[ymin, ymax]` using a Python random function

Step (2): Discard the coordinate and choose another random one, if `[xr, yr]` does not lie within the triangle. There are different ways to check, if the point is inside a convex polygon like a triangle, e.g.:

• Dividing the triangle in three sub-triangles and checking, if the area of the three sub-triangles has the same size as the original triangle
• Checking for each line of the triangle, if the random coordinate lies on the same side of the plane as the third point of the triangle
• Using barycentric coordinates

The latter two strategies are explained in more detail in this article

There are more methods, but these three are easy to implement in Python even with little mathematical background.