I've written an inefficient but simple algorithm in Java to see how close I could get to doing some basic clustering on a set of points, more or less as described in the question.

The algorithm works on a list if (x,y) coords `ps`

that are specified as `int`

s. It takes three other parameters as well:

- radius (
`r`

): given a point, what is the radius for scanning for nearby points
- max addresses (
`maxA`

): what are the maximum number of addresses (points) per cluster?
- min addresses (
`minA`

): minimum addresses per cluster

Set `limitA=maxA`

.
**Main iteration:**
Initialize empty list `possibleSolutions`

.
**Outer iteration:** for every point `p`

in `ps`

.
Initialize empty list `pclusters`

.
A worklist of points `wps=copy(ps)`

is defined.
Workpoint `wp=p`

.
**Inner iteration:** while `wps`

is not empty.
Remove the point `wp`

in `wps`

. Determine all the points `wpsInRadius`

in `wps`

that are at a distance < `r`

from `wp`

. Sort `wpsInRadius`

ascendingly according to the distance from `wp`

. Keep the first `min(limitA, sizeOf(wpsInRadius))`

points in `wpsInRadius`

. These points form a new cluster (list of points) `pcluster`

. Add `pcluster`

to `pclusters`

. Remove points in `pcluster`

from `wps`

. If `wps`

is not empty, `wp=wps[0]`

and continue inner iteration.
**End inner iteration.**
A list of clusters `pclusters`

is obtained. Add this to `possibleSolutions`

.
**End outer iteration.**

We have for each `p`

in `ps`

a list of clusters `pclusters`

in `possibleSolutions`

. Every `pclusters`

is then weighted. If `avgPC`

is the average number of points per cluster in `possibleSolutions`

(global) and `avgCSize`

is the average number of clusters per `pclusters`

(global), then this is the function that uses both these variables to determine the weight:

```
private static WeightedPClusters weigh(List<Cluster> pclusters, double avgPC, double avgCSize)
{
double weight = 0;
for (Cluster cluster : pclusters)
{
int ps = cluster.getPoints().size();
double psAvgPC = ps - avgPC;
weight += psAvgPC * psAvgPC / avgCSize;
weight += cluster.getSurface() / ps;
}
return new WeightedPClusters(pclusters, weight);
}
```

The best solution is now the `pclusters`

with the least weight. We repeat the main iteration as long as we can find a better solution (less weight) than the previous best one with `limitA=max(minA,(int)avgPC)`

. **End main iteration.**

Note that for the same input data this algorithm will always produce the same results. Lists are used to preserve order and there is *no random* involved.

To see how this algorithm behaves, this is an image of the result on a test pattern of 32 points. If `maxA=minA=16`

, then we find 2 clusters of 16 addresses.

Next, if we decrease the minimum number of addresses per cluster by setting `minA=12`

, we find 3 clusters of 12/12/8 points.

And to demonstrate that the algorithm is far from perfect, here is the output with `maxA=7`

, yet we get 6 clusters, some of them small. So you still have to guess too much when determining the parameters. Note that `r`

here is only 5.

Just out of curiosity, I tried the algorithm on a larger set of randomly chosen points. I added the images below.

Conclusion? This took me half a day, it is inefficient, the code looks ugly, and it is relatively slow. But it shows that it is possible to produce *some* result in a short period of time. Of course, this was just for fun; turning this into something that is actually useful is the hard part.