# What's an efficient way to find if a point lies in the convex hull of a point cloud?

I have a point cloud of coordinates in numpy. For a high number of points, I want to find out if the points lie in the convex hull of the point cloud.

I tried pyhull but I cant figure out how to check if a point is in the ConvexHull:

hull = ConvexHull(np.array([(1, 2), (3, 4), (3, 6)]))
for s in hull.simplices:
s.in_simplex(np.array([2, 3]))


raises LinAlgError: Array must be square.

Here is an easy solution that requires only scipy:

def in_hull(p, hull):
"""
Test if points in p are in hull

p should be a NxK coordinates of N points in K dimensions
hull is either a scipy.spatial.Delaunay object or the MxK array of the
coordinates of M points in Kdimensions for which Delaunay triangulation
will be computed
"""
from scipy.spatial import Delaunay
if not isinstance(hull,Delaunay):
hull = Delaunay(hull)

return hull.find_simplex(p)>=0


It returns a boolean array where True values indicate points that lie in the given convex hull. It can be used like this:

tested = np.random.rand(20,3)
cloud  = np.random.rand(50,3)

print in_hull(tested,cloud)


If you have matplotlib installed, you can also use the following function that calls the first one and plots the results. For 2D data only, given by Nx2 arrays:

def plot_in_hull(p, hull):
"""
plot relative to in_hull for 2d data
"""
import matplotlib.pyplot as plt
from matplotlib.collections import PolyCollection, LineCollection

from scipy.spatial import Delaunay
if not isinstance(hull,Delaunay):
hull = Delaunay(hull)

# plot triangulation
poly = PolyCollection(hull.points[hull.vertices], facecolors='w', edgecolors='b')
plt.clf()
plt.title('in hull')
plt.plot(hull.points[:,0], hull.points[:,1], 'o', hold=1)

# plot the convex hull
edges = set()
edge_points = []

"""Add a line between the i-th and j-th points, if not in the list already"""
if (i, j) in edges or (j, i) in edges:
return
edge_points.append(hull.points[ [i, j] ])

for ia, ib in hull.convex_hull:

lines = LineCollection(edge_points, color='g')
plt.show()

# plot tested points p - black are inside hull, red outside
inside = in_hull(p,hull)
plt.plot(p[ inside,0],p[ inside,1],'.k')
plt.plot(p[-inside,0],p[-inside,1],'.r')

• Is it lso possible to find the outer points of the convex hull of a point cloud? Because I want to remove those points from a distance calculation that are form the outer triangles and often have high distances Commented Apr 10, 2018 at 17:08
• It's quite simple actually: let cloud be a NxK arrays of N points in K dimension, ConvexHull(cloud).vertices (from scipy.spatial) gives the indices of the points on the convex hull, i.e. the "outer points"
– Juh_
Commented Apr 12, 2018 at 7:32
• You can safely assume it is a reliable method, as it is explained in the doc of Delaunay.find_simplex which returns -1 for point outside of the hull. Now, if you want more control, or want a faster algorithm, I recommend the solution of @nils below. It's more complex but compute only what is needed (I didn't test it, but it looks like it is)
– Juh_
Commented May 6, 2019 at 15:23
• Yes: ConvexHull doesn't provide the suitable api. Here I propose to use a method that does more than required but is easy to implement. Note that I stop using scipy couple of years ago, so it could evolve.
– Juh_
Commented May 7, 2019 at 15:21
• 'TypeError: float() argument must be a string or a number' on line hull = Delaunay(hull). Any ideas? Commented Nov 27, 2019 at 16:51

I would not use a convex hull algorithm, because you do not need to compute the convex hull, you just want to check whether your point can be expressed as a convex combination of the set of points of whom a subset defines a convex hull. Moreover, finding the convex hull is computationally expensive, especially in higher dimensions.

In fact, the mere problem of finding out whether a point can be expressed as a convex combination of another set of points can be formulated as a linear programming problem.

import numpy as np
from scipy.optimize import linprog

def in_hull(points, x):
n_points = len(points)
n_dim = len(x)
c = np.zeros(n_points)
A = np.r_[points.T,np.ones((1,n_points))]
b = np.r_[x, np.ones(1)]
lp = linprog(c, A_eq=A, b_eq=b)
return lp.success

n_points = 10000
n_dim = 10
Z = np.random.rand(n_points,n_dim)
x = np.random.rand(n_dim)
print(in_hull(Z, x))


For the example, I solved the problem for 10000 points in 10 dimensions. The executions time is in the ms range. Would not want to know how long this would take with QHull.

• @Juh_: Denote {x_1,...,x_n} as set of n points, {w_1,...,w_n} as variable weights, and y as the point that you want to describe through a combination of these n points. Then \sum_i w_i x_i = y_i and , then you want to
– Nils
Commented May 24, 2018 at 3:49
• @Juh_: ... make sure that \sum_i w_i = 1 and w_i >= 0. I used linear programming to find w_i, but there may be other ways.
– Nils
Commented May 24, 2018 at 3:56
• @Juh_ That's tricky. I cannot write math here. Scipy assumes you have the following problem: min_x {c'w | Aw=b, w>=0}, where w are the variables, c are objective coefficients, and Aw=b are the constraints (w>=0 is default in LP). As c is zero, there is no real optimization. The solver simply checks feasibility, i.e., whether there exists a w such that Aw=b is satisfied. Now, in our case b = [y_1,...,y_d,1] and A = [[x_11 w_1,...,x_n1 w_n],...,[x_1d w_1,...,x_nd w_n],[w_1,...,w_n]]. In the code above the query point y is called x and the point set x is called 'points'.
– Nils
Commented May 25, 2018 at 9:47
• @Juh_ "Why is it necessary to add the "scaling" dimension (the 1s)?" This is the requirement for having a convex combination, otherwise you'd check if the point lies in a cone, which is not what you want.
– Nils
Commented May 25, 2018 at 9:50
• Good solution. But I find that it is very slow when I check if 10 000 points belong to convex hull
– user9562553
Commented Dec 30, 2019 at 14:02

Hi I am not sure about how to use your program library to achieve this. But there is a simple algorithm to achieve this described in words:

1. create a point that is definitely outside your hull. Call it Y
2. produce a line segment connecting your point in question (X) to the new point Y.
3. loop around all edge segments of your convex hull. check for each of them if the segment intersects with XY.
4. If the number of intersection you counted is even (including 0), X is outside the hull. Otherwise X is inside the hull.
5. if so occurs XY pass through one of your vertexes on the hull, or directly overlap with one of your hull's edge, move Y a little bit.
6. the above works for concave hull as well. You can see in below illustration (Green dot is the X point you are trying to determine. Yellow marks the intersection points.
• +1 Nice approach. It is probably easier, for a convex hull, to find a point that's definitely inside the hull (the average of all the hull vertices) then follow your method with reversed conditions for success. Commented Feb 11, 2014 at 14:35
• Although this is a little nitpicky, there are a couple cases where this will fail: 1) If you pick a point that is colinear with a pair of vertices on the hull and the test point is also colinear with those vertices as well, then you would technically get an infinite number of intersections. 2) if your test point and X and outer point Y are colinear with a vertex on the intersection of an odd number of facets (3d case) then you would erroneously conclude that the test point is actually inside of the hull... at the very least, you may need to check for case 2. E.g. ensure non-colinearity of XYV Commented Oct 6, 2017 at 18:34
• also, note that some of polygon in the example are not convex hulls, for a convex hull you will find at most two intersection. It is also not immediate to me how to select a point that is "definitely outside" the hull. Maybe easier to find a point "definitely inside" (e.g. barycenter) and see if it has one or zero intersections, that also remove colinearity problems (I am assuming the hull is a convex polygon). Commented May 30, 2018 at 18:17
• This requires the convex hull (as a polygon) to be found first. But this step is not necessary for the overall task, as Nils's solution shows. Commented Sep 15, 2019 at 16:08
• @Vincenzooo if you find the minimal point (in a lexicographical ordering) and then subtract by some amount in all dimensions you are definitely outside the hull. In addition, sometimes you might have extra knowledge about what range the points can lie in which makes the task trivial. Commented Jan 30, 2020 at 8:45

First, obtain the convex hull for your point cloud.

Then loop over all of the edges of the convex hull in counter-clockwise order. For each of the edges, check whether your target point lies to the "left" of that edge. When doing this, treat the edges as vectors pointing counter-clockwise around the convex hull. If the target point is to the "left" of all of the vectors, then it is contained by the polygon; otherwise, it lies outside the polygon.

This other Stack Overflow topic includes a solution to finding which "side" of a line a point is on: Determine Which Side of a Line a Point Lies

The runtime complexity of this approach (once you already have the convex hull) is O(n) where n is the number of edges that the convex hull has.

Note that this will work only for convex polygons. But you're dealing with a convex hull, so it should suit your needs.

It looks like you already have a way to get the convex hull for your point cloud. But if you find that you have to implement your own, Wikipedia has a nice list of convex hull algorithms here: Convex Hull Algorithms

• If someone has already calculated the convex hull of points, then this approach is the simplest one. Commented Jul 23, 2016 at 10:22

Use the equations attribute of ConvexHull:

def point_in_hull(point, hull, tolerance=1e-12):
return all(
(np.dot(eq[:-1], point) + eq[-1] <= tolerance)
for eq in hull.equations)


In words, a point is in the hull if and only if for every equation (describing the facets) the dot product between the point and the normal vector (eq[:-1]) plus the offset (eq[-1]) is less than or equal to zero. You may want to compare to a small, positive constant tolerance = 1e-12 rather than to zero because of issues of numerical precision (otherwise, you may find that a vertex of the convex hull is not in the convex hull).

Demonstration:

import matplotlib.pyplot as plt
import numpy as np
from scipy.spatial import ConvexHull

points = np.array([(1, 2), (3, 4), (3, 6), (2, 4.5), (2.5, 5)])
hull = ConvexHull(points)

np.random.seed(1)
random_points = np.random.uniform(0, 6, (100, 2))

for simplex in hull.simplices:
plt.plot(points[simplex, 0], points[simplex, 1])

plt.scatter(*points.T, alpha=.5, color='k', s=200, marker='v')

for p in random_points:
point_is_in_hull = point_in_hull(p, hull)
marker = 'x' if point_is_in_hull else 'd'
color = 'g' if point_is_in_hull else 'm'
plt.scatter(p[0], p[1], marker=marker, color=color)


• Can you explain why a point is in the hull if and only if for every equation (describing the facets) the dot product between the point and the normal vector (eq[:-1]) plus the offset (eq[-1]) is less than or equal to zero? This is not clear to me. What is the physical meaning of that dot product, for a single equation? I am guessing it would mean "the facet's normal points at the point", but I fail to see why it is so Commented Dec 2, 2019 at 13:13
• This statement follows from one way of defining the convex hull. From the documentation of Qhull (the code used by scipy): "The convex hull of a point set P is the smallest convex set that contains P. If P is finite, the convex hull defines a matrix A and a vector b such that for all x in P, Ax+b <= [0,...]" The rows of A are the unit normals; the elements of b are the offsets. Commented Dec 4, 2019 at 2:25
• it's a good solution. But it's a little slow for a convex hull membership test for 10,000 two-dimensional points
– user9562553
Commented Dec 30, 2019 at 14:04
• I've shared a vectorized version of the function. Commented Jun 3, 2022 at 2:01

Just for completness, here is a poor's man solution:

import pylab
import numpy
from scipy.spatial import ConvexHull

def is_p_inside_points_hull(points, p):
global hull, new_points # Remove this line! Just for plotting!
hull = ConvexHull(points)
new_points = numpy.append(points, p, axis=0)
new_hull = ConvexHull(new_points)
if list(hull.vertices) == list(new_hull.vertices):
return True
else:
return False

# Test:
points = numpy.random.rand(10, 2)   # 30 random points in 2-D
# Note: the number of points must be greater than the dimention.
p = numpy.random.rand(1, 2) # 1 random point in 2-D
print is_p_inside_points_hull(points, p)

# Plot:
pylab.plot(points[:,0], points[:,1], 'o')
for simplex in hull.simplices:
pylab.plot(points[simplex,0], points[simplex,1], 'k-')
pylab.plot(p[:,0], p[:,1], '^r')
pylab.show()


The idea is simple: the vertices of the convex hull of a set of points P won't change if you add a point p that falls "inside" the hull; the vertices of the convex hull for [P1, P2, ..., Pn] and [P1, P2, ..., Pn, p] are the same. But if p falls "outside", then the vertices must change. This works for n-dimensions, but you have to compute the ConvexHull twice.

Two example plots in 2-D:

False:

True:

• I'm digging it! But I will say this: CURSE OF DIMENSIONALITY. Over 8 dimensions and the kernel splits. Commented Apr 28, 2016 at 18:39

It looks like you are using a 2D point cloud, so I'd like to direct you to the inclusion test for point-in-polygon testing of convex polygons.

Scipy's convex hull algorithm allows for finding convex hulls in 2 or more dimensions which is more complicated than it needs to be for a 2D point cloud. Therefore, I recommend using a different algorithm, such as this one. This is because as you really need for point-in-polygon testing of a convex hull is the list of convex hull points in clockwise order, and a point that is inside of the polygon.

The time performance of this approach is as followed:

• O(N log N) to construct the convex hull
• O(h) in preprocessing to calculate (and store) the wedge angles from the interior point
• O(log h) per point-in-polygon query.

Where N is the number of points in the point cloud and h is the number of points in the point clouds convex hull.

Building on the work of @Charlie Brummitt, I implemented a more efficient version enabling to check if multiple points are in the convex hull at the same time and replacing any loop by faster linear algebra.

import numpy as np
from scipy.spatial.qhull import _Qhull

def in_hull(points, queries):
hull = _Qhull(b"i", points,
options=b"",
furthest_site=False,
incremental=False,
interior_point=None)
equations = hull.get_simplex_facet_array()[2].T
return np.all(queries @ equations[:-1] < - equations[-1], axis=1)

# ============== Demonstration ================

points = np.random.rand(8, 2)
queries = np.random.rand(3, 2)
print(in_hull(points, queries))


Note that I'm using the lower-level _Qhull class for efficiency.

• I got this error: cannot import name '_Qhull' from 'scipy.spatial.qhull' Commented Jun 17, 2022 at 20:52
• Yes, this is because your version of scipy is very recent. _Qhull is no longer exposed. So you have no other choice than using an older version of scipy or the slightly slower python interface. Commented Jun 17, 2022 at 22:10

To piggy-back off of this answer, to check all points in a numpy array at once, this worked for me:

import matplotlib.pyplot as plt
import numpy as np
from scipy.spatial import ConvexHull

points = np.array([(1, 2), (3, 4), (3, 6), (2, 4.5), (2.5, 5)])
hull = ConvexHull(points)

np.random.seed(1)
random_points = np.random.uniform(0, 6, (100, 2))

# get array of boolean values indicating in hull if True
hull.equations[:,-1]) <= tolerance, axis=1)

random_points_in_hull = random_points[in_hull]


def points_in_hull(p, hull, tol=1e-12):
return np.all(hull.equations[:,:-1] @ p.T + np.repeat(hull.equations[:,-1][None,:], len(p), axis=0).T <= tol, 0)


where p is now a [N,2] array. It is ~6 times faster than the recommended solution (@Sildoreth answer), and ~10 times faster than the original.

Adapted demonstration without the for loop: (pasted from below to avoid searching in the thread)

import matplotlib.pyplot as plt
import numpy as np
from scipy.spatial import ConvexHull

points = np.array([(1, 2), (3, 4), (3, 6), (2, 4.5), (2.5, 5)])
hull = ConvexHull(points)

np.random.seed(1)
random_points = np.random.uniform(0, 6, (100, 2))

for simplex in hull.simplices:
plt.plot(points[simplex, 0], points[simplex, 1])

plt.scatter(*points.T, alpha=.5, color='k', s=200, marker='v')

in_hull = points_in_hull(random_points, hull)
plt.scatter(random_points[in_hull,0], random_points[in_hull,1], marker='x', color='g')
plt.scatter(random_points[~in_hull,0], random_points[~in_hull,1], marker='d', color='m')


If you want to keep with scipy, you have to convex hull (you did so)

>>> from scipy.spatial import ConvexHull
>>> points = np.random.rand(30, 2)   # 30 random points in 2-D
>>> hull = ConvexHull(points)


then build the list of points on the hull. Here is the code from doc to plot the hull

>>> import matplotlib.pyplot as plt
>>> plt.plot(points[:,0], points[:,1], 'o')
>>> for simplex in hull.simplices:
>>>     plt.plot(points[simplex,0], points[simplex,1], 'k-')


So starting from that, I would propose for computing list of points on the hull

pts_hull = [(points[simplex,0], points[simplex,1])
for simplex in hull.simplices]


(although i did not try)

And you can also come with your own code for computing the hull, returning the x,y points.

If you want to know if a point from your original dataset is on the hull, then you are done.

I what you want is to know if a any point is inside the hull or outside, you must do a bit of work more. What you will have to do could be

• for all edges joining two simplices of your hull: decide whether your point is above or under

• if point is below all lines, or above all lines, it is outside the hull

As a speed up, as soon as a point has been above one line and below one another, it is inside the hull.

• I want to find out, if an arbitrary point is in the convex hull of the point-cloud or outside of it. :)
– AME
Commented May 25, 2013 at 15:54
• so are you satisfied with answer ? Commented May 25, 2013 at 15:56
• Your answer for inside or outside the hull isn't correct in that above and below is not a sufficient test. For example, if a point is just outside the hull but, say, midway along a 45deg diagonal, then your test will fail. Instead, sum the angles between the test point and all the points of the convex hull: if it's inside the angles will sum to 2pi, and if it's outside they'll sum to 0 (or I might have some detail of this wrong, but that's the basic idea). Commented May 25, 2013 at 17:54
• maybe we are not clear about what is above/under a line. I assume that a line has only two sides, above and under. then the test works if you consider all pairs of points from the hull. Commented May 25, 2013 at 18:31

Based on this post, here is my quick-and-dirty solution for a convex regions with 4 sides (you can easily extend it to more)

def same_sign(arr): return np.all(arr > 0) if arr[0] > 0 else np.all(arr < 0)

a =  pts - pt
d = np.zeros((4,2))
d[0,:] = pts[1,:]-pts[0,:]
d[1,:] = pts[2,:]-pts[1,:]
d[2,:] = pts[3,:]-pts[2,:]
d[3,:] = pts[0,:]-pts[3,:]
res = np.cross(a,d)
return same_sign(res), res

points = np.array([(1, 2), (3, 4), (3, 6), (2.5, 5)])

np.random.seed(1)
random_points = np.random.uniform(0, 6, (1000, 2))

res = np.array([inside_quad(points, p)[0] for p in random_points])
print res[:4]
plt.plot(random_points[:,0], random_points[:,1], 'b.')
plt.plot(random_points[res][:,0], random_points[res][:,1], 'r.')


• You can replace hard-coded indexes into: d = np.roll(pts, 2) - pts Commented Apr 22, 2021 at 8:09

Vectorized, with plotting (based on other great answers here: 1, 2 ):

import matplotlib.pyplot as plt
import numpy as np
from scipy.spatial import ConvexHull

def points_in_hull(points: np.ndarray, hull: ConvexHull, tolerance: float = 1e-12):
return np.all(np.add(points @ hull.equations[:, :-1].T, hull.equations[:, -1]) <= tolerance, axis=1)

points = np.array([(1, 2), (3, 4), (3, 6), (2, 4.5), (2.5, 5)])
hull = ConvexHull(points)

np.random.seed(1)
random_points = np.random.uniform(0, 6, (1000, 2))

in_hull = points_in_hull(random_points, hull)
random_points_in_hull = random_points[in_hull]

# plot
fig, ax = plt.subplots(figsize=(20, 10))
plt.scatter(random_points[:, 0], random_points[:, 1], color='blue')
plt.scatter(points[:, 0], points[:, 1], color='green')
plt.scatter(random_points_in_hull[:, 0], random_points_in_hull[:, 1], color='red')
for simplex in hull.simplices:
plt.plot(points[simplex, 0], points[simplex, 1], 'k-')
plt.show()