One problem you would face if using
scipy.cluster.vq.kmeans is that that function uses Euclidean distance to measure closeness. To shoe-horn your problem into one solveable by
k-means clustering, you'd have to find a way to convert your strings into numerical vectors and be able to justify using Euclidean distance as a reasonable measure of closeness.
That seems... difficult. Perhaps you are looking for Levenshtein distance instead?
Note there are variants of the K-means algorithm that can work with non-Euclideance distance metrics (such as Levenshtein distance).
K-medoids (aka PAM), for instance, can be applied to data with an arbitrary distance metric.
For example, using
Pycluster's implementation of
nltk's implementation of Levenshtein distance,
import nltk.metrics.distance as distance
import Pycluster as PC
words = ['apple', 'Doppler', 'applaud', 'append', 'barker',
'baker', 'bismark', 'park', 'stake', 'steak', 'teak', 'sleek']
dist = [distance.edit_distance(words[i], words[j])
for i in range(1, len(words))
for j in range(0, i)]
labels, error, nfound = PC.kmedoids(dist, nclusters=3)
cluster = dict()
for word, label in zip(words, labels):
for label, grp in cluster.items():
yields a result like
['apple', 'Doppler', 'applaud', 'append']
['stake', 'steak', 'teak', 'sleek']
['barker', 'baker', 'bismark', 'park']