Be careful, if you plan to scale up your algorithm to many points, probing for points nearby is better done using a *spatial index*. I'm not aware of the existence of spatial indexes using polar coordinates, and I'm sure they would be a bit complex to implement/use. So if you have:

- lots of points,
- probe more frequently than moving points,

ask yourself the question whether you should use Cartesian coordinates and a spatial index.

Do the math yourself according to your typical use case:

Using cartesian alongside polar coordinates:

- Converting polar to cartesian is done only when a point moves, and involve two trigonometric functions;
- Finding points nearest than a certain distance to another point may be done in O(1) time (depending on the average distance, the size of the spatial index, the number of points...), and does not involve anything other than adds/multiplies (not even square roots, you compare the distance squared).

Using polar coordinates only:

- Scanning for all points w/o spatial index is O(n);
- This involves one trigonometric function per comparison (thus
*n* trig calls per probe).

Be aware that trigs are bloody expensive in computation time.