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I had a question regarding 2 line segments. Say we have 2 line segments whose origin and lengths are given as: (P0, L0) and (P1, L1) respectively. I need to find when can they end at the same point. The line segments lie anywhere in 3D space.

One of the approaches I could think of is: Let's say this common end point is T and the points are A and B. So for the line segments with A and B as origins, A,B and T must form a triangle. Length of vector AT = L0 and length of vector BT = L1. But since the orientation of the line segment is not known, there can be a lot of possibilities. Lets say we choose a particular orientation for line segment AT as (i,j,k) - 1st octant. So now we can move anywhere in space from T but only by a distance L1 to find BT.

This is where I m not sure how to move forward.

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1 Answer 1

The line segments can end in the same point if and only if the distance between P0 and P1 is less than or equal to L0 + L1. In the special case where this distance is equal to L0 + L1 the line segments have the same orientation in space and lie on the same line.

A way to think about this is to ask if two spheres around P0 and P1 with radii L0 and L1 intersect or at least touch each other. The circle (point) of intersection (touch) is where your line segments can have the same end point.

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vow! i did not think about the sphere intersection interpretation. The special case you mentioned. Are you sure they have the same orientation? That could be one of the solutions. Wouldn't d = L0 + L1 be also the case when the three points form a triangle? One more thing. Once we test for this, what range of values would be acceptable if I want to run an iteration of values to test. –  RJSkywalker Jan 6 '13 at 3:54
    
I am sure they form a single line. For a detailed explanation, look up the "triangle inequality". Your triangle will be collapsed to flat line in the case of d == L0 + L1. No need to test. Proven math. –  s.bandara Jan 6 '13 at 4:08
    
oh yea understood. what about the value ranges? Do I need to individually put in values because I want the function to return a list of all the valid common end points –  RJSkywalker Jan 6 '13 at 8:01
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Aha, that is harder. There are infinitely many points though in a circle. Do you want a parametric representation? –  s.bandara Jan 6 '13 at 8:24
    
yes, i think parametric representation might be the only way to represent all the points. How else could I do it? Maybe I might need an additional constraint like the points should be within a particular region –  RJSkywalker Jan 6 '13 at 19:13

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