# whats is the difference between “k means” and “fuzzy c means” objective functions?

I am trying to see if the performance of both can be compared based on the objective functions they work on?

-
Come on! Do not close... clustering IS programming related, at the same level that say sorting algorithms or questions on formal grammar! – mjv Feb 27 '10 at 1:51

BTW, the Fuzzy-C-Means (FCM) clustering algorithm is also known as Soft K-Means.

The objective functions are virtually identical, the only difference being the introduction of a vector which expresses the percentage of belonging of a given point to each of the clusters. This vector is submitted to a "stiffness" exponent aimed at giving more importance to the stronger connections (and conversely at minimizing the weight of weaker ones); incidently, when the stiffness factor tends towards infinity the resulting vector becomes a binary matrix, hence making the FCM model identical to that of the K-Means.

I think that except for some possible issue with the clusters which have no points assigned to them, it is possible to emulate the K-Means algorithm with that of the FCM one, by simulating an infinite stiffness factor (= by introducing a function which changes the biggest value in the vector to 1, and zeros out the other values, in lieu of the exponentiation of the vector). This is of course a very inefficient way of running a K-Means, because the algorithm then has to perform as many operations as with a true FCM (if only with 1 and 0 values, which does simplify the arithmetic, but not the complexity)

With regards to performance, the FCM therefore needs to perform k (i.e. number of clusters) multiplications for each point, for each dimension (not counting also the exponentiation to take stiffness into account). This, plus the overhead needed for computing and managing the proximity vector, explains why FCM is quite slower than plain K-Means.

But FCM/Soft-K-Means is less "stupid" than Hard-K-Means when it comes for example to elongated clusters (when points otherwise consistent in other dimensions tend to scatter along a particular dimension or two), and that's why it's still around ;-)

Also, I just thought about this, but haven't put any "mathematical" thought to it, FCM may converge faster than hard K-Means, somewhat offsetting the bigger computational requirement of FCM.

-
Why should FCM converge faster? It doesn't really converge at all, you have to stop at a certain threshold, when the relative assignments do no longer change "enough"; just like GMM-EM clustering. – Anony-Mousse Jun 1 '13 at 11:13
@Anony-Mousse : Both FCM and K-Means converge, in the mathematical sense, that is very much what you describe with `when the relative assignments do no longer change "enough".` In other words the clustering solution provided by successive iterations of these algorithms change a lot, at first, from one iteration to the next, but eventually the changes become smaller and smaller as the function approaches its limit. It is safe to stop iterating after a practical change threshold is reached because the function is convergent: iterating more won't produce a significantly different result... – mjv Jun 3 '13 at 15:13
... What I am yet to try and study, is whether FCM actually converges faster than hard K-Means. In other words if it takes fewer iterations with FCM (than with plain K-Means) to reach the desired "stable" solution. – mjv Jun 3 '13 at 15:16
k-means actually converges with `epsilon=0`. FCM doesn't. So they converge quite differently in nature IMHO. – Anony-Mousse Jun 3 '13 at 16:13

K-Means clustering and Fuzzy-C Means Clustering are very similar in approaches. The main difference is that, in Fuzzy-C Means clustering, each point has a weighting associated with a particular cluster, so a point doesn't sit "in a cluster" as much as has a weak or strong association to the cluster, which is determined by the inverse distance to the center of the cluster.

Fuzzy-C means will tend to run slower than K means, since it's actually doing more work. Each point is evaluated with each cluster, and more operations are involved in each evaluation. K-Means just needs to do a distance calculation, whereas fuzzy c means needs to do a full inverse-distance weighting.

-