# The Algorithm to Find the Point of Intersection of Two 3D Line Segment

Finding the point of intersection for two 2D line segment is easy; the formula is straight forward. But finding the point of intersection for two 3D line segment is not, I afraid.

What is the algorithm, in C# preferably that finds the point of intersection of two 3D line segments?

I found a C++ implementation here. But I don't trust the solution because it makes preference of a certain plane ( look at the way `perp` is implemented under the implementation section, it assumes a preference for `z plane`. Any generic algorithm must not assume any plane orientation or preference).

Is there a better solution?

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I like the math in your answer, but I don't think your statement about a generic algorithm is true. Projecting the lines onto the xy-plane will turn the problem into a 2d problem. Then, find the intersection of the resulting points/lines and test its validity. Choosing z is just an implementation convenience. Working in a lower dimension might reduce the operation count, too. –  Derek E Feb 23 '10 at 21:33
@Derek, I'm not sure whether projecting lines onto the xy-plane is a good idea. Consider this assuming there are two x-y lines, each located on different `z` planes. If you project them to the xy planes then they will appear to be intersecting, even though they are not. –  Graviton Feb 24 '10 at 1:28
Soon Hui, Yes, that is correct. After determining the intersection in the xy-plane, you would need to test its validity. This is just a matter of "plugging the numbers back in". The upside is if the numbers don't check, then you can conclude that the lines don't intersect. Note: you would need to handle a couple of special cases (one line is directed along z-hat, parallel lines). On a related note, the solution you posted below assumes that the lines are infinite. You would need to do a validation test on that solution, as well. –  Derek E Feb 24 '10 at 2:45
@Derek, my solution would be easier and cleaner to implement because I just need to check for `a` and `b` must be between 0 and 1 –  Graviton Feb 24 '10 at 3:21
@DerekE - NO. I'm afraid you are wrong. Projecting into a 2-d plane can easily fail, even when a solution does exist. Consider two line segments, at least one of which is parallel to the z axis. Now the projection will be a point. –  user85109 Jun 7 '13 at 15:30
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``````// This code in C++ works for me in 2d and 3d

// assume Coord has members x(), y() and z() and supports arithmetic operations
// that is Coord u + Coord v = u.x() + v.x(), u.y() + v.y(), u.z() + v.z()

inline Point
dot(const Coord& u, const Coord& v)
{
return u.x() * v.x() + u.y() * v.y() + u.z() * v.z();
}

inline Point
norm2( const Coord& v )
{
return v.x() * v.x() + v.y() * v.y() + v.z() * v.z();
}

inline Point
norm( const Coord& v )
{
return sqrt(norm2(v));
}

inline
Coord
cross( const Coord& b, const Coord& c) // cross product
{
return Coord(b.y() * c.z() - c.y() * b.z(), b.z() * c.x() - c.z() * b.x(), b.x() *  c.y() - c.x() * b.y());
}

bool
intersection(const Line& a, const Line& b, Coord& ip)
// http://mathworld.wolfram.com/Line-LineIntersection.html
// in 3d; will also work in 2d if z components are 0
{
Coord da = a.second - a.first;
Coord db = b.second - b.first;
Coord dc = b.first - a.first;

if (dot(dc, cross(da,db)) != 0.0) // lines are not coplanar
return false;

Point s = dot(cross(dc,db),cross(da,db)) / norm2(cross(da,db));
if (s >= 0.0 && s <= 1.0)
{
ip = a.first + da * Coord(s,s,s);
return true;
}

return false;
}
``````
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Most 3D lines do not intersect. A reliable method is to find the shortest line between two 3D lines. If the shortest line has a length of zero then you know that the two original lines intersect.

A method for finding the shortest line between two 3D lines can be found on Paul Bourke's website which is an excellent geometry resource. The site has been reorganized, so scroll down to find the topic.

http://paulbourke.net/geometry/pointlineplane/

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+1. The only answer to have clearly recognized the issues. –  user85109 Jun 7 '13 at 15:33

I found a solution: it's here.

The idea is to make use of vector algebra, to use the `dot` and `cross` to simply the question until this stage:

``````a (V1 X V2) = (P2 - P1) X V2
``````

and calculate the `a`.

Note that this implementation doesn't need to have any planes or axis as reference.

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Hello, i used the solution you presented, but sometimes i get mirrored results... you had this problem too? –  user3252833 May 23 at 14:51

You might find it useful to take a look at a corresponding article in Wikipedia - it does not have a code, but the algorithm is described pretty well, imho (but you should know some math anyway).

http://en.wikipedia.org/wiki/Bentley%e2%80%93Ottmann_algorithm

Update: funny enough is that Russian version of the same Wikipedia entry contains more details (and formular) and an algorithm description is pseudo-code as well. Here's a link to translation of this entry to English (via Google Translate):

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The wiki entry contains only description of 2D one –  Graviton Feb 23 '10 at 8:13
Man, I said that you should know some math - it's easy to draw a generalized version (you just need to add one more component (coordinate)) –  AlexS Feb 23 '10 at 8:19
Seems to me like Ottmann algorithm actually describes the strategies how to to find efficiently the lists intersection points if there are a list of lines, but as to how to actually find the intersection point, it doesn't say. See the pseudo code here for my point: softsurfer.com/Archive/algorithm_0108/… –  Graviton Feb 23 '10 at 8:37
If we extend the 2D way of doing things, you will have three equations (`x`,`y` and `z`) for two unknowns (`u`,`v`). It is definitely nontrivial to solve it. –  Graviton Feb 23 '10 at 8:39