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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!

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A very simple example showing how you find the first best might be useful... – tim_yates Dec 1 '11 at 18:23
@tim_yates Wikipedia says: "Starting with the root node, the algorithm moves down the tree recursively, in the same way that it would if the search point were being inserted (i.e. it goes left or right depending on whether the point is less than or greater than the current node in the split dimension). Once the algorithm reaches a leaf node, it saves that node point as the 'current best.'" Is that what you're talking about? I'm doing that right now, but I'm not sure where to go from there. – Benjamin Kovach Dec 1 '11 at 18:41

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