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A Computational Geometry problem:
The point P0 is chosen randomly on an edge (e.g.,EB) of a polygon (e.g.,BCDE), to find possible points (i.e., P1,P2,P3,...) on other edges based on the given distance (i.e., r). The following demonstration shows a solution by finding intersections between the circle centered on the point P0 and the edges of polygon. So the problem basically could be solved by Circle--Line-Segment intersection analysis.

I wonder is there any more efficient method for this very simple problem in terms of computation cost? The process will be evaluated several million times so any improvemnt is of interest.

  • the final solution will benefit from Python power;
  • the core computation will be in Fortran if required.

enter image description here

Thanks for your comments. Please consider my comments on comments which helps to clarify the question more. Not willing to repeat them here, encouraging to consider all comments and answers ;).

I just implemented the method of Circle--Line-Segment Intersection based on the algorithm found [here]. Actually I adapted it to work with line-segments. The benchmark of the algorithm implemented in Python is as follows:
enter image description here
enter image description here
The number of line segments is: 100,000 and the system is usual desktop. The elapsed time is: 15 seconds. Hope these are helpful to give some idea of computation cost. Implementation of core in Fortan could improve the performance significantly.
However the translation is the last step.

share|improve this question
Is the distance r of all million queries the same? Can we count on the polygon to be convex? – Boris Strandjev Jan 23 '12 at 8:31
@BorisStrandjev For our problem all polygons are convex. r could vary for each iteration so it could be varying but is constant for each polygon individually. – Developer Jan 23 '12 at 8:59
And are the millions of queries done in a single polygon or in different? – Boris Strandjev Jan 23 '12 at 9:03
You forgot to mark one intersection, to the left of P1, in the picture – Wesley Jan 23 '12 at 9:06
@Wesley That is by purpose. The interest is intersections not on the same edge of the point. – Developer Jan 23 '12 at 9:09
up vote 2 down vote accepted

For intersection between line (or line-segment) and a circle (sphere in 3D) there is a bit more explanation, implementation details and also Python, C etc sample codes in [this link]. You may try them for your problem.
The idea is basically the same as you have already found in [here].

share|improve this answer
the link is dead – Alnitak Sep 6 '14 at 15:19

Assuming the circle--line-intersection is optimized, you might be able to gain something by distinguishing between different cases:

for point A, B:

  • If d(P0, A) < r and d(P0, B) < r: No intersection

  • if d(P0, A) == r: Intersection at A

  • if d(P0, B) == r: Intersection at B
  • If d(P0, A) < r and d(P0, B) > r: 1 intersection, execute circle--line-intersection
  • If d(P0, A) > r and d(P0, B) < r: 1 intersection, execute circle--line-intersection

  • If d(P0, A) > r and d(P0, B) > r: There is either 0, 1 or 2 intersections -> If the minimum distance to line (A, B) > r: No intersections -> If the minimum distance to line (A, B) == r: 1 intersection -> If the minimum distance to line (A, B) < r: 2 intersections

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In the last case I believe you meant d(P0, P2) > r. – Coffee on Mars Jan 23 '12 at 9:17
Note that the circle centered on P0, so all intersections lie on the circle and so their distances are equal to r. That is d(P0,*)=r. Am I missing something from your answer? – Developer Jan 23 '12 at 9:23
Sorry I confused the intersections with the actual points.. I'll fix the answer, hopefully it makes more sense then – Wesley Jan 23 '12 at 9:29
last case should be d(P0, A) > r and d(P0, B) > r and it can have either 0, 1 (tangent) or 2 intersections – soulcheck Jan 23 '12 at 11:37
Thanks @soulcheck, you're right. Fixed it. – Wesley Jan 23 '12 at 15:08

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