The problem of distributing an arbitrary number of people upon a given set of locations is an optimization problem. More specifically, it can be interpreted as a clustering problem. A nice clustering example implemented in JS can be found at the A Curious Animal blog.

As you can see in the above example, *clustering* means grouping of neighbouring locations. In other words, it is a computation that yields an optimal distribution of groups of locations (clusters) upon a given set of locations. If we declare that *a cluster* is *a person* instead of *a location group* we get to your problem statement.

Since the number of people is your input, I'd suggest k-means clustering algorithm (short explanation, available software list @wikipedia).

EDIT:

When working with optimization algorithms in general there are two caveats:

- the chosen algorithm is designed to solve your (class of) problem
- some input parameter combination can lead to odd, non acceptable results

The first point requires some knowledge of the algorithm, while the second is a matter of try-and-error as you nicely noticed. Also, the suptile differences in input can result in huge differences in output.

The above link states that the k-means algorithm "does not work well with non-globuar clusters".

It will be easier to start from his opposite - a globular cluster which is defined as: "A more precise mathematical term is convex, which roughly means that any line you can draw between two cluster members stays inside the boundaries of the cluster.":

A non-globular cluster (non-convex set of points) looks like this:

Probably your "thin ovoid clusters" are non-convex?

Another important characteristic (also stated in the above link) is that k-means is a non-deterministic algorithm, meaning that it may (and most probably will) yield different outputs for the same input when ran multiple times.

This happens because the algorithm makes the initial partitioning of clusters at random - and the final output is highly sensitive of that initial partitioning. Depending on the implementation used, you may have some space for modifying here.

If that doesn't lead to satisfying results the only thing left is to try another algorithm (since the locations are given). I'll suggest QT clustering algorithm that I use in a commercial product. It is a deterministic clustering algorithm which takes as input the minimal cluster size, and the threshold distance - distance of the point from the center of the cluster.

But, with this approach you will need to modify the algorithm itself. The algorithm usually stops when "no more clusters can be formed having the minimum cluster size.". You'll need to modify the algorithm to stop when a wanted amount of clusters has been reached. The minimum cluster size value should be OK as 1, but you might want to try out different values for the threshold distance.

Here is some code sample in C# that I stumbled upon. Hope it was helpful.