Well there are two practical solutions to the the problem of intelligent selection
of the number of centroids (k) in common use.

The first is to **PCA** your data, and the output from PCA--which is the
principal components (eigenvectors) and their cumulate contribution to the variation
observed in the data--obviously suggests an optimal number of centroids.
(E.g., if 95% of the variability in your data is explained by the first three principal
components, then k=3 is a wise choice for k-means.)

The second commonly used practical solution to intelligently estimate k is
is a revised implementation of the k-means algorithm, called **k-means++**. In essence,
k-means++ just differs from the original k-means by the additional of a pre-processing
step. During this step, the number and initial position of the centroids and estimated.

The algorithm that k-means++ relies on to do this is straightforward to understand and to implement in code. A good source for both is a 2007 Post in the *LingPipe Blog*, which offers an excellent
explanation of k-means++ as well as includes a citation to the original paper that
first introduced this technique.

Aside from providing an optimal choice for k, k-means++ is apparently superior to
the original k-means in both performance (roughly 1/2 processing time compared
with k-means in one published comparison) and accuracy (three orders of magnitude
improvement in error in the same comparison study).

`R`

) over here: stackoverflow.com/a/15376462/1036500