# Fast way to compute the minimal distance of two sets of k-dimensional vectors

I two sets of k-dimensional vectors, where k is around 500 and the number of vectors is usually smaller. I want to compute the (arbitrarily defined) minimal distance between the two sets. A naive approach would be this:

``````(loop for a in set1
for b in set2
minimizing (distance a b))
``````

However, this requires O(n² * distance) computations. Is there a faster way of doing this?

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Put the two sets of coordinates into a Spatial Index, e.g. a KD-tree.

You then compute the intersection of these two indices.

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While this link may answer the question, it is better to include the essential parts of the answer here and provide the link for reference. Link-only answers can become invalid if the linked page changes. –  hims056 Aug 22 '12 at 12:05

I don't think you can do better than O(n^2) when the distance is arbitrary (you have to examine each of the possible distances!). For a given distance function we might be able to exploit the properties of the function, but there won't be any general algorithm which works with any distance function in better than O(n^2) (i.e. o(n^2) : note smallOh).

If your data is dynamic and you have to keep obtaining the closest pair of points at different times, for arbitrary distance function the following papers by Eppstein will probably help (which have special update operations in order to make finding the closest pair of points quick):

You will be able to adapt the above one set algorithms to a two set algorithm (for instance, by defining distance between points of same set to be infinity).

For Euclidean type (L^p) distance, there are known O(nlogn) time algorithms, which work with a given set of points (i.e. you dont need to have any special update algorithms):

Of course, the L^p is for one set, but you might be able to adapt it for two sets.