# 3D line hits a 3D point?

I want to create a function wich knows if a line hits a point. Is there any function like that? I also want to set the size of my 3D-points in centimetre and dont know how to do that.

For example:

Assuming that the points have an radius and the lines wouldnt hit the point exact in the middle, is the a function that shows me if a line hit the point?

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Oh man, that's tough (in general). I'm curious to know as well! –  Henry Gomersall Jul 20 '12 at 9:49
how your line and a sphere represented? Why do you use `matplotlib` tag? –  J.F. Sebastian Jul 20 '12 at 10:13
Surely if you know the equation of the line (ax + by + cz = 0) you can substitute the values for a, b and c (coordinates of the point) then check that -d < ax + by + cz < d where d is the diameter of the points. Or am I missing the points? –  jaypeagi Jul 20 '12 at 16:54

I think what you actually want to compute is the distance between point and line in 3d

and when the distance is smaller than the radius of the sphere around your point, you have a match.

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Thank you for that. But how can I set the size of my points to for example 0.3 centimetres? –  Daniel Zemljic Jul 20 '12 at 11:17
that depends on the units you use for the rest of the calculation. you just have to specify line and point in 3d also in centimeters. then you can just check if the resulting distance d is smaller than 0.3 centimeters. –  Dirk Jul 20 '12 at 11:25

Ok, I have classical solution that work in any dimensions.

First of all, you got sphere and a line, and you need to have good model of them. Sphere is easy you just have a Vector `.center` and `.diameter`.

``````class Sphere:
def __init__( sphere, center, diameter ):
sphere.center=Vector(center)
sphere.diameter=float(diameter)
``````

Line could be more problematic for beginners because it could be defined in many ways. The most useful comes from parametric equation, you have a direction in Vector `.direction` and some staring point `.center`. We assume that `.direction` is unit length, and `.center` is the nearest point on line from (0,0). In most cases we need to create a line, having to points Vectors:

``````def line_on_two_points( A, B ):
return Line( direction= Vector(B)-A, center=A )
``````

So we have to fix the `direction` and `center` in the constructor. `.direction` is easy to fix wee need just to make it unit length. To find `.center`, we need scalar projection. Here is as vector to D:

Having `.direction` as unit length A to B and `center` as from C to A, we could init our line as:

``````class Line:
def __init__( line, direction, center ):
line.direction= Vector(direction) / length(direction)
line.center= center - line.direction*dot(center,line.direction)
``````

If we don't have a line, just two points we could just do:

``````#class Sphere:
def colide_line_on_two_points( sphere, A, B ):
line=line_on_two_points( A-sphere.center, B-sphere.center)
return length(line.center) < sphere.diameter
``````

But when we have a line we try to optimize it as:

``````#class Sphere:
def colide_line( sphere, line ):
return line.distance_to(sphere.center) < sphere.diameter
``````

The `.distance_to()` function is a bit tricky:

``````#class Line:

def vector_to( line, P ):
return line.center + line.direction * dot(line.direction,P) - P

def distance_to( line, P ):
return length( line.center + line.direction * dot(line.direction,P) - P )

def move_to( line, P ):
line.center += line.direction * dot(line.direction,P) - P
``````

The last but not least is the `Vector` type, I try numpy, but it's rather slow for 2D,3D:

``````from numpy import array as Vector
from numpy import dot
from numpy.linalg import norm as length
``````
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What you are looking for is an algorithm to find intersections between a line and a sphere. This is a problem commonly found in graphics programming, and there are a lot of articles that probably explain it a lot better than I could. There is one at http://www.lighthouse3d.com/tutorials/maths/ray-sphere-intersection/

The basic idea is that you project the sphere onto the line, and then solve the resulting right triangle , formed by the point of intersection, the sphere's center, and the projected point, using the Pythagorean theorem.

Here is the code I used in my pathtracing renderer:

``````hitdata intersectwith(Sphere sphere)
{
d3Vector projected;

float t = V.dot(sphere.pos.subtract(O));
projected = V.normalize().scalarmultiply(t); //the projected vector
float distnce = (projected.subtract(sphere.pos.subtract(O))).magnitude();
//the length between the center of your sphere and the projected point
hitdata outdata; // a class containing the results of the intersection
outdata.hit = false;
outdata.t = 110;
if(t<=0)
{
return outdata;
}
if(distnce<sphere.r)
{// the line is less distant from the center of the sphere than the surface
outdata.hit = true;
float deltaT = sqrtf((sphere.r*sphere.r)-(distnce*distnce));//Pythagorean theorem