I personally use the following approach:

**Pseudo code**:

```
int k = 1;
double oldCompactness = std::numeric_limits<double>::max();
double compactness = kmeans(data, k);
while( compactness/oldCompactness < threshold ) {
oldCompactness = compactness;
k = k + 1;
compactness = kmeans(data, k);
}
```

The compactness is decreasing with increasing number of clusters (it should become zero if you have as many clusters as data points).

I should point out that the optimal number of clusters is very application dependent. For example in your application I don't know if you prefer high data reduction (low k) or a good visual representation (high k) or a compromise (*somewhere* in between).

You can look here for more/better ideas. Or here (week 8) if you prefer video.