I have been thinking about a variation of the closest pair problem in which the only available information is the set of distances already calculated (we are not allowed to sort points according to their x-coordinates).

Consider 4 points (A, B, C, D), and the following distances:

```
dist(A,B) = 0.5
dist(A,C) = 5
dist(C,D) = 2
```

In this example, I don't need to evaluate `dist(B,C)`

or `dist(A,D)`

, because it is guaranteed that these distances are greater than the current known minimum distance.

Is it possible to use this kind of information to reduce the O(n²) to something like O(nlogn)?

Is it possible to reduce the cost to something close to O(nlogn) if I accept a kind of approximated solution? In this case, I am thinking about some technique based on reinforcement learning that only converges to the real solution when the number of reinforcements go to infinite, but provides a great approximation for small n.

Processing time (measured by the big O notation) is not the only issue. To keep a very large amount of previous calculated distances can also be an issue.

Imagine this problem for a set with 10⁸ points.

What kind of solution should I look for? Was this kind of problem solved before?

This is not a classroom problem or something related. I have been just thinking about this problem.

`dist(A,B) = 0.5; dist(A,C) = 5`

, the closest B and C can possibly be is if A, B, and C are colinear, and in that order. This leads to`dist(B,C) >= 4.5`

, which is greater than the current shortest path, so there's no need to evaluate. – Trojan Dec 27 '13 at 3:08