### Bounty

This question raises several issues. The bounty will go to an answer which addresses them holistically.

Here's a problem I've been playing with.

**NOTE** I'm especially interested in solutions that are **not based in Euclidian space.**

There is a set of Actors which form a crowd of size K. The distance `d(ActorA,ActorB)`

is easily computable for any two actors (solutions should work for various definitions of 'distance') and we can find the set of N nearest neighbours for any given Actor using any of a number of established algorithms.

This neighbour set is correct at the first instant but **the Actors are always moving** and I want to maintain the evolving list of N nearest neighbours for each Actor. What I am interested in is *approximate* solutions which are more efficient than perfect solutions.

**Solutions should converge to correctness**after errors have been introduced.- It is acceptable to sometimes perform a full recomputation if the errors become too large but
**detecting these errors should be cheap**.

So far I have been using a *friend-of-a-friend* algorithm:

```
recompute_nearest (Actor A)
{
Actor f_o_f [N*N];
for each Actor n in A.neighbours
append n to f_o_f if n != A and n not in f_o_f
Distance distances [N*N];
for 0 <= i < f_o_f.size
distances [i] = distance (A, f_o_f [i])
sort (f_o_f, distances)
A .neighbours = first N from f_o_f
}
```

This performs reasonably well when the crowd is slow-moving and N is suitably large. It converges after small errors, satisfying the first criteria, but

- I don't have good way to detect large errors,
- I have no quantitative description of the size and frequency of errors,
- it converges in practice but I can't
*prove*that it always will.

Can you help with any of these points?

Also, do you know of any alternative approaches which perform well

- when the crowd is fast-moving,
- when
*some*actors are fast-moving, - when N is small,
- when the crowd is sparse in some places and dense in others,
- or with particular spacial-indexing algorithms?

The extension I'm working on at the moment is to generalise friend-of-a-friend to take the friend-of-a-friend-of-a-friend in cases when a neighbour is fast-moving. I suspect that this doesn't scale to well and it's hard to derive the right parameters without a quantification of the errors.

I welcome all suggestions! It's a fun little problem :-)

### Notable Suggestions So Far

Fexvez: sample random extra neighbours, sample size depending on the speed of the Agent. *Sampling from the area it's about to move into would probably also help.*

Resample the neighbours when an agents `speed*delta_time`

exceeds the distance to the furthest known neighbour.

Maintain the Delaunay triangulation which is a superset of the nearest-neighbour graph. *Only accounts for one nearest neighbour.*

David Mount's ANN library *Doesn't seem to handle moving bodies.*

exactmetric (there may be heuristics under some circumstances); you can assume smooth movement within each timestep but velocities are dynamic; in this particular application it's more like travellers than a flock (N flocks intermingling might be an interesting model actually), and "efficient" refers to time more than space. – spraff Sep 19 '11 at 8:13