**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.

**Updates:**

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:

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.

`r`

of all million queries the same? Can we count on the polygon to be convex? – Boris Strandjev Jan 23 '12 at 8:31`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