I have successfully written a function that traverses a Kd-Tree for the nearest single neighbor of a point.

However, I'm trying to switch this function around so that it finds the K-nearest neighbors instead of just the single one. This is proving to be a much more daunting task than I originally imagined, and I'm finding myself in need of some help...

The wikipedia article on kD-trees says:

The algorithm can be extended in several ways by simple modifications. It can provide the k-Nearest Neighbours to a point by maintaining k current bests instead of just one. Branches are only eliminated when they can't have points closer than any of the k current bests.

...but it doesn't say anything about how to obtain the **initial** current bests. Finding the first "best" is simple enough, but I don't know how to go about finding the rest of the k-current bests without removing the previous best and searching all over again...which basically defeats the point of having a fast algorithm cause I'd have to do it k (in my case, 17) times.

If I have a populated list of the 17 initial "bests," I believe my algorithm will find the correct points.

I apologize if this is vague. If any code samples are needed, I'd be glad to provide them. Though if there is a simple explanation for this issue, it's probably unnecessary to post it so I won't initially.

Thanks in advance!

very simpleexample showing how you find the first best might be useful... – tim_yates Dec 1 '11 at 18:23