Don't mix the problem and the algorithm.

The k-means problem is finding the least-squares assignment to centroids.

There are multiple algorithms for finding a solution.

There is an obvious approach to find the global optimum: **enumerating all **`k^n`

possible assignments - that *will* yield a global minimum, but in exponential runtime.

Much more attention was put to finding an approximate solution in *faster* time.

The Lloyd/Forgy algorithm is an EM-style iterative model refinement approach, that is guaranteed to converge to a *local* minimum simply because there is a finite number of states, and the objective function must decrease in every step. This algorithm runs in `O(n*k*i)`

where `i << n`

usually, but it may find a local minimum only.

The MacQueens method is technically not iterative. It's a single-pass, one-element-at-a-time algorithm that will not even find a local minimum in the Lloyd sense. (You can however run it multiple passes over the data set, until convergence, to get a local minimum too!) If you do a single pass, its in `O(n*k)`

, for multiple passes add `i`

. It may or may not take more passes than Lloyd.

Then there is Hartigan and Wong. I don't remember the details, IIRC it was a clever, more lazy, variant of Lloyd/Forgy, so probably in `O(n*k*i)`

, too (although probably not recomputing all `n*k`

distances for later iterations?)

You could also do a randomized alogrithm that just tests `l`

random assignments. It probably won't find a minimum at all, but run in "linear" time `O(n*l)`

.

Oh, and you can try different random initializations, to improve your chances of finding the global minimum. Add a factor `t`

for the number of trials...