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# Circle-Polygon intersections

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.

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:

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.

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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

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].

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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