So I decided to write down the (theoretical) solution I came up with. Partly because it might help me (see below for more on this) and partly to have a decent solution for anyone interested. It's a system of linear equations that one could solve by using the Simplex Algorithm.

The constrains I came up with are:

1) Every object is in exactly one cluster

2) Every cluster has at most M (*constant*) objects

3) A dimension of a cluster is true iff at least one of the objects in that cluster has that dimension set as true

I will explain how the constrains are enforces now:

Let there be n objects and k clusters. We consider the sum (in the following this is one row)

x_{1}^{1} + x_{2}^{1} + x_{3}^{1} + ... + x_{n}^{1} + d_{1}^{1} + d_{2}^{1} + d_{3}^{1} + ... + d_{n}^{1} +

x_{1}^{2} + x_{2}^{2} + x_{3}^{2} + ... + x_{n}^{2} + d_{1}^{2} + d_{2}^{2} + d_{3}^{2} + ... + d_{n}^{2} +

...

x_{1}^{k} + x_{2}^{k} + x_{3}^{k} + ... + x_{n}^{k} + d_{1}^{k} + d_{2}^{k} + d_{3}^{k} + ... + d_{n}^{k}

where

x_{a}^{c} is true iff object a is int cluster c

d_{b}^{c} is true iff the dimension b in cluster c is true

Since it is always better (or at least never harmful) to cluster objects, we know the number of clusters is *ceil(objects divided by M)*. For simplicity I will leave out the variables now and just write the coefficients.

**1)** Every object is in exactly one cluster

10...0 0...0 10...0 0...0 10...0 0...0 ... 10...0 0...0 = 1

010...0 0...0 010...0 0...0 010...0 0...0 ... 010...0 0...0 = 1

...

0..01 0...0 0...01 0...0 0...01 0...0 ... 0...01 0...0 = 1

This will enforce every object to be in exactly one cluster. This could theoretical allow the objects to be with parts (<1) in several clusters. But because we are looking for the optimal solution this will not happen.

**2)** Every cluster has at most M (*constant*) objects

11...1 0...0 0...0 0...0 0...0 0...0 ... 0...0 0...0 <= M

0...0 0...0 11...1 0...0 0...0 0...0 ... 0...0 0...0 <= M

...

0...0 0...0 0...0 0...0 0...0 0...0 ... 11...1 0...0 <= M

The sum of objects is not bigger than M. This constrain should be clear.

Now comes the tricky part:

**3)** A dimension of a cluster is true iff at least one of the objects in that cluster has that dimension set as true

For every dimension and every cluster consider those elements that have this dimension set to true (we could also consider the false one, but they don't matter). We now write a line for each of them (and each cluster)

0..010...0 -10...0 0...0 0...0 ... 0...0 0...0 <= 0

where the 1 denotes that this dimension for this object (in this cluster) is set to true and the -1 one identifies the dimension (in this case the first one). If the object is set in this cluster, the dimension for this cluster has to be 1 (1*1 -1*d <= 0), if it's not set the dimension can also be zero (0*1 - 1*d <= 0).

For the second dimension in the first cluster this would look like this:

0..010...0 0-10...0 0...0 0...0 ... 0...0 0...0 <= 0

and for the last cluster and the last dimension like this

0...0 0...0 0...0 0...0 ... 0..010..0 0...0-1 <= 0

Now we can simply minimize the sum of the x_{a}^{c} and we are done.

*This could probably be written down in a better way, but I hope it's understandable.*

Now the problem is the following:
I'm working with 70 clusters, 3000 objects and 2300 dimensions. Using the approach above this results in 371000 variables (clusters * objects + clusters * dimensions) and 1292095 rows (estimating rows as objects + cluster + dimensions * log(objects) * clusters)

I'm tending to believe that the optimal solution is not feasible. Even if you can still optimize the approach described here, it is unlikely that a similar approach will perform much better. So now I'm looking for good approximations, any ideas how to tackle this problem are welcome.

Thank you :)