I suppose something to try is reshaping the array of distances into a 1-D array, where you keep careful record of how that new 1-D index will map back into the 2-D index. Then just call a sorting function on the 1-D array, to sort it into ascending order. Make sure to save the permutation of the indices that causes the sort, and then read-off the 2-D array coordinates that correspond to the 1-D coordinates in the sort permutation. In this method, you'll be at the mercy of Matlab's sort algorithms, and you'll need to keep careful track of the index changes from reshaping.
This also poses a problem for removing points from consideration. You would have to keep a running list of indices for points that have already been selected, and if (as you traverse the 1-D permutation) you encounter something that corresponds to an index already selected, then you just skip it (e.g. you don't set it to NaN, you just skip it from consideration).
This saves you from needing to compute a minimum every time. The only real checking at each iteration of a for-loop that traverses the 1-D sort permutation is the logical check whether the current location has been selected before (due to one of its points being involved in a smaller distance location). On iteration
i, this check takes at most
i-1 comparisons, so this will be slightly less than O(n^2).
This will be faster than your current method, which calculates the min of the whole array every time, but still not as fast as the O(n log n) method mentioned in the link below.
More generally, you want to read the papers linked in the answers to this question. This is not a trivial problem, not well suited for the RAM intensive Matlab sessions, and probably will require you to rewrite your whole approach to this.
Another idea is that if you broadcast all of the array
A to a bunch of processors, then this is embarrassingly parallel on the points in array
B. You can ship out pieces of
B to different processors, and get back a list of all the distances. You'll have to do some processing back on the head node to select out the index for the min-distance and remove those points, but not too much. Probably you can re-write that part anyway so that you don't need to compute the distances multiple times.
So if you write this in, say, Python or C++, you could quickly use the MPI library and then either run it on a cloud cluster at Amazon Web Services, or on a local cluster if you have access.