# Shortest distance between two line segments

I need a function to find the shortest distance between two line segments. A line segment is defined by two endpoints. So for example one of my line segments (AB) would be defined by the two points A (x1,y1) and B (x2,y2) and the other (CD) would be defined by the two points C (x1,y1) and D (x2,y2).

Feel free to write the solution in any language you want and I can translate it into javascript. Please keep in mind my geometry skills are pretty rusty. I have already seen http://stochastix.wordpress.com/2008/12/28/distance-between-two-lines/ and I am not sure how to translate this into a function. Thank you so much for help.

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–  devnullicus Jul 11 '12 at 7:48

Is this in 2 dimensions? If so, the answer is simply the shortest of the distance between point A and line segment CD, B and CD, C and AB or D and AB. So it's a fairly simple "distance between point and line" calculation (if the distances are all the same, then the lines are parallel).

This site explains the algorithm for distance between a point and a line pretty well.

It's slightly more tricky in the 3 dimensions because the lines are not necessarily in the same plane, but that doesn't seem to be the case here?

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But if the segments intersect, the minimum distance between each endpoint and its opposite segment could still be nonzero....or have I misunderstood the problem? –  Jim Lewis May 13 '10 at 5:07
Oh yeah, I missed that particular case :) If they intersect then obviously the minimum distance is 0. Paul Bourke to the rescue again: local.wasp.uwa.edu.au/~pbourke/geometry/lineline2d –  Dean Harding May 13 '10 at 5:15
Yes codeka this is in 2D. I was thinking there was something more elegant than having to repeat distance check four times. But this makes sense and I accept this answer. –  Frank May 13 '10 at 5:29
Either I'm missing something or the algorithm will not work for (0,0)-(1,0) and (2,1)-(2,2). Correct distance is sqrt(2) and the algorithm will give 1. –  maxim1000 Dec 9 '12 at 5:31
@maxim1000: In my description, "AB" represents the line segment A->B, I've edited to make that clear. If you go to the site I linked to (I've also updated the link, it looks like it's moved) you can see the algorithm for distance between a point and a line is actually very similar to the algorithm for the distance between a point and a line segment (i.e. you just limit the value of u to the range [0,1]). –  Dean Harding Dec 9 '12 at 14:28

Taken from this example, which also comes with a simple explanation of why it works as well as VB code (that does more than you need, so I've simplified as I translated to Python -- note: I have translated, but not tested, so a typo might have slipped by...):

def segments_distance(x11, y11, x12, y12, x21, y21, x22, y22):
""" distance between two segments in the plane:
one segment is (x11, y11) to (x12, y12)
the other is   (x21, y21) to (x22, y22)
"""
if segments_intersect(x11, y11, x12, y12, x21, y21, y22, y22): return 0
# try each of the 4 vertices w/the other segment
distances = []
distances.append(point_segment_distance(x11, y11, x21, y21, x22, y22))
distances.append(point_segment_distance(x12, y12, x21, y21, x22, y22))
distances.append(point_segment_distance(x21, y21, x11, y11, x12, y12))
distances.append(point_segment_distance(x22, y22, x11, y11, x12, y12))
return min(distances)

def segments_intersect((x11, y11, x12, y12, x21, y21, x22, y22):
""" whether two segments in the plane intersect:
one segment is (x11, y11) to (x12, y12)
the other is   (x21, y21) to (x22, y22)
"""
dx1 = x12 - x11
dy1 = y12 - y11
dx2 = x22 - x21
dy2 = y22 - y21
delta = dx2 * dy1 - dy2 * dx1
if delta == 0: return False  # parallel segments
s = (dx1 * (y21 - y11) + dy1 * (x11 - x21)) / delta
t = (dx2 * (y11 - y21) + dy2 * (x21 - x11)) / (-delta)
return (0 <= s <= 1) and (0 <= t <= 1)

import math
def point_segment_distance(px, py, x1, y1, x2, y2):
dx = x2 - x1
dy = y2 - y1
if dx == dy == 0:  # the segment's just a point
return math.hypot(px - x1, py - y1)

# Calculate the t that minimizes the distance.
t = ((px - x1) * dx + (py - y1) * dy) / (dx * dx + dy * dy)

# See if this represents one of the segment's
# end points or a point in the middle.
if t < 0:
dx = px - x1
dy = py - y1
elif t > 1:
dx = px - x2
dy = py - y2
else:
near_x = x1 + t * dx
near_y = y1 + t * dy
dx = px - near_x
dy = py - near_y

return math.hypot(dx, dy)
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This is very good example thank you. –  Frank May 13 '10 at 5:40

For calculating the minimum distance between 2 2D line segments it is true that you have to perform 4 perpendicular distance from endpoint to other line checks successively using each of the 4 endpoints. However, if you find that the perpendicular line drawn out does not intersect the line segment in any of the 4 cases then you have to perform 4 additional endpoint to endpoint distance checks to find the shortest distance.

Whether there is a more elegent solution to this I do not know.

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That's for the 3D case, I don't think Frank needs this in 3D... –  Dean Harding May 13 '10 at 5:15
I have seen this link as well but this is for 3D. I do not think it applies here? –  Frank May 13 '10 at 5:20
2D is just a special case of 3D... –  Lasse V. Karlsen May 13 '10 at 5:21
(n)D is just a special case of (n + 1)D. –  Jon Purdy May 13 '10 at 6:01

This is my solution in python. Works with 3d points and you can simplify for 2d.

import numpy as np
def closestDistanceBetweenLines(a0,a1,b0,b1):
''' Given two lines defined by numpy.array pairs (a0,a1,b0,b1)
Return distance, and the two closest points
'''
A = a1 - a0
B = b1 - b0

A = A / np.linalg.norm(A)
B = B / np.linalg.norm(B)
cross = np.cross(A, B);

# If denominator is 0, lines are parallel
denom = np.linalg.norm(cross)**2

if (denom == 0):
return None

# Calculate the dereminent and return points
t = (b0 - a0);
det0 = np.linalg.det([t, B, cross])
det1 = np.linalg.det([t, A, cross])

t0 = det0/denom;
t1 = det1/denom;

pA = a0 + (A * t0);
pB = b0 + (B * t1);

d = np.linalg.norm(pA-pB)

return d,pA,pB

a1=np.array([-9,10,1])
a0=np.array([-9,10,1])
a1=np.array([22,-1,-10])
b0=np.array([8,-7,1])
b1=np.array([8,10,-16])
closestDistanceBetweenLines(a0,a1,b0,b1)
Result: (3.1192028523190358, array([ 9.39900249,  3.4713217 , -5.5286783 ]), array([ 8. ,  1.5, -7.5]))
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