A Computational Geometry problem:
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.
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.