# How do I compute the intersection point of two lines?

I have two lines that intersect at a point. I know the endpoints of the two lines. How do I compute the intersection point in Python?

``````# Given these endpoints
#line 1
A = [X, Y]
B = [X, Y]

#line 2
C = [X, Y]
D = [X, Y]

# Compute this:
point_of_intersection = [X, Y]
``````
• Are these line segments, or lines? – user2357112 supports Monica Dec 19 '13 at 9:31
• This problem mostly boils down to "do the math". You can use algebraic manipulation to find an expression for the coordinates of the intersection, then insert that expression into your program. Remember to check for parallel lines first, though. – user2357112 supports Monica Dec 19 '13 at 9:33
• Search stackoverflow before ask a question : [the answer][1] [1]: stackoverflow.com/questions/3252194/… – Cao Manh Dat Dec 19 '13 at 9:33
• “I know how to do this on paper” — Then what exactly is your problem? It’s pure math which you need to apply here. And Python is your calculator. What have you tried? – poke Dec 19 '13 at 9:34
• possible duplicate of How can I check if two segments intersect? – Jerry Coffin Dec 19 '13 at 9:43

Unlike other suggestions, this is short and doesn't use external libraries like `numpy`. (Not that using other libraries is bad...it's nice not need to, especially for such a simple problem.)

``````def line_intersection(line1, line2):
xdiff = (line1[0][0] - line1[1][0], line2[0][0] - line2[1][0])
ydiff = (line1[0][1] - line1[1][1], line2[0][1] - line2[1][1])

def det(a, b):
return a[0] * b[1] - a[1] * b[0]

div = det(xdiff, ydiff)
if div == 0:
raise Exception('lines do not intersect')

d = (det(*line1), det(*line2))
x = det(d, xdiff) / div
y = det(d, ydiff) / div
return x, y

print line_intersection((A, B), (C, D))
``````

And FYI, I would use tuples instead of lists for your points. E.g.

``````A = (X, Y)
``````

EDIT: Initially there was a typo. That was fixed Sept 2014 thanks to @zidik.

This is simply the Python transliteration of the following formula, where the lines are (a1, a2) and (b1, b2) and the intersection is p. (If the denominator is zero, the lines have no unique intersection.)

$\mathbf{p} = \frac{ \begin{vmatrix} \begin{vmatrix}\mathbf{a_1} & \mathbf{a_2}\end{vmatrix} & \mathbf{a_1} - \mathbf{a_2} \\ \begin{vmatrix}\mathbf{b_1} & \mathbf{b_2}\end{vmatrix} & \mathbf{b_1} - \mathbf{b_2} \end{vmatrix} }{\begin{vmatrix}\mathbf{a_1} - \mathbf{a_2} & \mathbf{b_1} - \mathbf{b_2}\end{vmatrix}}$

• This solution yields (1.0, 2.0) for intersecting `line_intersection(((0.5, 0.5), (1.5, 0.5)), ((1, 0), (1, 2)))`, which should be (1, 0.5). – xtofl Aug 11 '14 at 1:14
• I have to agree with @xtofl - this doesn't work. I get false positives and negatives. – rbaleksandar Sep 8 '16 at 12:57
• Î would also avoid using exceptions here. A simple `False` would do and it's not as expensive as handling an exception. – rbaleksandar Sep 8 '16 at 13:12
• This solution doesn't work for points that intersect at (0.,0.) – Lee Feb 23 '17 at 15:58
• I guess after all these comments, now we know why it makes sense to use numpy.. – Pithikos Mar 13 at 23:22

Can't stand aside,

So we have linear system:

A1 * x + B1 * y = C1
A2 * x + B2 * y = C2

let's do it with Cramer's rule, so solution can be found in determinants:

x = Dx/D
y = Dy/D

where D is main determinant of the system:

A1 B1
A2 B2

and Dx and Dy can be found from matricies:

C1 B1
C2 B2

and

A1 C1
A2 C2

(notice, as C column consequently substitues the coef. columns of x and y)

So now the python, for clarity for us, to not mess things up let's do mapping between math and python. We will use array `L` for storing our coefs A, B, C of the line equations and intestead of pretty `x`, `y` we'll have `[0]`, `[1]`, but anyway. Thus, what I wrote above will have the following form further in the code:

for D

L1[0] L1[1]
L2[0] L2[1]

for Dx

L1[2] L1[1]
L2[2] L2[1]

for Dy

L1[0] L1[2]
L2[0] L2[2]

Now go for coding:

`line` - produces coefs A, B, C of line equation by two points provided,
`intersection` - finds intersection point (if any) of two lines provided by coefs.

``````from __future__ import division

def line(p1, p2):
A = (p1[1] - p2[1])
B = (p2[0] - p1[0])
C = (p1[0]*p2[1] - p2[0]*p1[1])
return A, B, -C

def intersection(L1, L2):
D  = L1[0] * L2[1] - L1[1] * L2[0]
Dx = L1[2] * L2[1] - L1[1] * L2[2]
Dy = L1[0] * L2[2] - L1[2] * L2[0]
if D != 0:
x = Dx / D
y = Dy / D
return x,y
else:
return False
``````

Usage example:

``````L1 = line([0,1], [2,3])
L2 = line([2,3], [0,4])

R = intersection(L1, L2)
if R:
print "Intersection detected:", R
else:
print "No single intersection point detected"
``````
• Works well, very fast – Alex Black Jun 20 '16 at 0:00
• This solution reports intersection where the lines COULD intersect given they have eternal lengths. – firelynx Sep 26 '16 at 14:18
• @firelynx I think you are confusing the term line with line segment. The OP asks for a line intersection (on purpose or due to not understanding the difference). When checking lines for intersections on has to take into account the fact that lines are infinite that is the rays that start from its midpoint (defined by the given coordinates of the two points that define it) in both directions. In a case of line segment intersection only the part of the line between the given points is checked for intersection and its infinite continuation is ignored. – rbaleksandar Oct 16 '16 at 13:29
• Btw how about coinciding lines? Using the algorithm above it returns `true` for two coinciding lines which can obviously not return a single point of intersection (since mathematically speaking there are infinite number of intersection points for this case). I think that the algorithms needs to handle this in a separate case since simply intersecting and coinciding lines are two very different cases. – rbaleksandar Nov 8 '16 at 15:19
• Yes @rbaleksandar, with this method - when `R` is `true` (`D != 0`) we can say only about intersecting lines. All other cases for `R` (when `D == 0`) can mean anything except intersecting (coinciding or parallel) lines. – rook Nov 10 '16 at 16:30

Using formula from: https://en.wikipedia.org/wiki/Line%E2%80%93line_intersection

`````` def findIntersection(x1,y1,x2,y2,x3,y3,x4,y4):
px= ( (x1*y2-y1*x2)*(x3-x4)-(x1-x2)*(x3*y4-y3*x4) ) / ( (x1-x2)*(y3-y4)-(y1-y2)*(x3-x4) )
py= ( (x1*y2-y1*x2)*(y3-y4)-(y1-y2)*(x3*y4-y3*x4) ) / ( (x1-x2)*(y3-y4)-(y1-y2)*(x3-x4) )
return [px, py]
``````

Here is a solution using the Shapely library. Shapely is often used for GIS work, but is built to be useful for computational geometry. I changed your inputs from lists to tuples.

# Problem

``````# Given these endpoints
#line 1
A = (X, Y)
B = (X, Y)

#line 2
C = (X, Y)
D = (X, Y)

# Compute this:
point_of_intersection = (X, Y)
``````

# Solution

``````import shapely
from shapely.geometry import LineString, Point

line1 = LineString([A, B])
line2 = LineString([C, D])

int_pt = line1.intersection(line2)
point_of_intersection = int_pt.x, int_pt.y

print(point_of_intersection)
``````

I didn't find an intuitive explanation on the web, so now that I worked it out, here's my solution. This is for infinite lines (what I needed), not segments.

Some terms you might remember:

A line is defined as y = mx + b OR y = slope * x + y-intercept

Slope = rise over run = dy / dx = height / distance

Y-intercept is where the line crosses the Y axis, where X = 0

Given those definitions, here are some functions:

``````def slope(P1, P2):
# dy/dx
# (y2 - y1) / (x2 - x1)
return(P2[1] - P1[1]) / (P2[0] - P1[0])

def y_intercept(P1, slope):
# y = mx + b
# b = y - mx
# b = P1[1] - slope * P1[0]
return P1[1] - slope * P1[0]

def line_intersect(m1, b1, m2, b2):
if m1 == m2:
print ("These lines are parallel!!!")
return None
# y = mx + b
# Set both lines equal to find the intersection point in the x direction
# m1 * x + b1 = m2 * x + b2
# m1 * x - m2 * x = b2 - b1
# x * (m1 - m2) = b2 - b1
# x = (b2 - b1) / (m1 - m2)
x = (b2 - b1) / (m1 - m2)
# Now solve for y -- use either line, because they are equal here
# y = mx + b
y = m1 * x + b1
return x,y
``````

Here's a simple test between two (infinite) lines:

``````A1 = [1,1]
A2 = [3,3]
B1 = [1,3]
B2 = [3,1]
slope_A = slope(A1, A2)
slope_B = slope(B1, B2)
y_int_A = y_intercept(A1, slope_A)
y_int_B = y_intercept(B1, slope_B)
print(line_intersect(slope_A, y_int_A, slope_B, y_int_B))
``````

Output:

``````(2.0, 2.0)
``````
• You may want to try this with these points: A1 = [1,1] A2 = [1,3] B1 = [1,3] B2 = [3,1] – Charlie Burns Nov 21 '17 at 22:19
• Anything that represents a line with y = ax + b will crash with vertical lines – Mehdi Feb 26 at 16:53

If your lines are multiple points instead, you can use this version.

``````import numpy as np
import matplotlib.pyplot as plt
"""
Sukhbinder
5 April 2017
Based on:
"""

def _rect_inter_inner(x1,x2):
n1=x1.shape[0]-1
n2=x2.shape[0]-1
X1=np.c_[x1[:-1],x1[1:]]
X2=np.c_[x2[:-1],x2[1:]]
S1=np.tile(X1.min(axis=1),(n2,1)).T
S2=np.tile(X2.max(axis=1),(n1,1))
S3=np.tile(X1.max(axis=1),(n2,1)).T
S4=np.tile(X2.min(axis=1),(n1,1))
return S1,S2,S3,S4

def _rectangle_intersection_(x1,y1,x2,y2):
S1,S2,S3,S4=_rect_inter_inner(x1,x2)
S5,S6,S7,S8=_rect_inter_inner(y1,y2)

C1=np.less_equal(S1,S2)
C2=np.greater_equal(S3,S4)
C3=np.less_equal(S5,S6)
C4=np.greater_equal(S7,S8)

ii,jj=np.nonzero(C1 & C2 & C3 & C4)
return ii,jj

def intersection(x1,y1,x2,y2):
"""
INTERSECTIONS Intersections of curves.
Computes the (x,y) locations where two curves intersect.  The curves
can be broken with NaNs or have vertical segments.
usage:
x,y=intersection(x1,y1,x2,y2)
Example:
a, b = 1, 2
phi = np.linspace(3, 10, 100)
x1 = a*phi - b*np.sin(phi)
y1 = a - b*np.cos(phi)
x2=phi
y2=np.sin(phi)+2
x,y=intersection(x1,y1,x2,y2)
plt.plot(x1,y1,c='r')
plt.plot(x2,y2,c='g')
plt.plot(x,y,'*k')
plt.show()
"""
ii,jj=_rectangle_intersection_(x1,y1,x2,y2)
n=len(ii)

dxy1=np.diff(np.c_[x1,y1],axis=0)
dxy2=np.diff(np.c_[x2,y2],axis=0)

T=np.zeros((4,n))
AA=np.zeros((4,4,n))
AA[0:2,2,:]=-1
AA[2:4,3,:]=-1
AA[0::2,0,:]=dxy1[ii,:].T
AA[1::2,1,:]=dxy2[jj,:].T

BB=np.zeros((4,n))
BB[0,:]=-x1[ii].ravel()
BB[1,:]=-x2[jj].ravel()
BB[2,:]=-y1[ii].ravel()
BB[3,:]=-y2[jj].ravel()

for i in range(n):
try:
T[:,i]=np.linalg.solve(AA[:,:,i],BB[:,i])
except:
T[:,i]=np.NaN

in_range= (T[0,:] >=0) & (T[1,:] >=0) & (T[0,:] <=1) & (T[1,:] <=1)

xy0=T[2:,in_range]
xy0=xy0.T
return xy0[:,0],xy0[:,1]

if __name__ == '__main__':

# a piece of a prolate cycloid, and am going to find
a, b = 1, 2
phi = np.linspace(3, 10, 100)
x1 = a*phi - b*np.sin(phi)
y1 = a - b*np.cos(phi)

x2=phi
y2=np.sin(phi)+2
x,y=intersection(x1,y1,x2,y2)
plt.plot(x1,y1,c='r')
plt.plot(x2,y2,c='g')
plt.plot(x,y,'*k')
plt.show()
``````