# Can I use K-means algorithm on a string?

I am working on a python project where I study RNA structure evolution (represented as a string for example: "(((...)))" where the parenthesis represent basepairs). The point being is that I have an ideal structure and a population that evolves towards the ideal structure. I have implemented everything however I would like to add a feature where I can get the "number of buckets" ie the k most representative structures in the population at each generation.

I was thinking of using the k-means algorithm but I am not sure how to use it with strings. I found scipy.cluster.vq but I don't know how to use it in my case.

thanks!

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K-means doesn't really care about the type of the data involved. All you need to do a K-means is some way to measure a "distance" from one item to another. It'll do its thing based on the distances, regardless of how that happens to be computed from the underlying data.

That said, I haven't used `scipy.cluster.vq`, so I'm not sure exactly how you tell it the relationship between items, or how to compute a distance from item A to item B.

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This answer doesn't make any sense. What is the "distance" between two strings of RNA such that it A) obeys the triangle inequality and B) is euclidean? There are many clustering algorithms, and it seems beyond me how k-means in particular would be useful in this circumstance. – sclv Jun 9 '11 at 16:51
The distance I am using is the structural distance, for example sequences: (1) "(((....)))" and (2) "((((..))))" Have a distance of 1 since the only difference in an insertion – Doni Jun 9 '11 at 20:35

K-means only works with euclidean distance. Edit distances such as Levenshtein don't even obey the triangle inequality may obey the triangle inequality, but are not euclidian. For the sorts of metrics you're interested in, you're better off using a different sort of algorithm, such as Hierarchical clustering: http://en.wikipedia.org/wiki/Hierarchical_clustering

Alternately, just convert your list of RNA into a weighted graph, with Levenshtein weights at the edges, and then decompose it into a minimum spanning tree. The most connected nodes of that tree will be, in a sense, the "most representative".

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Thanks, fixed! Embarrassingly, the author of the blog is a friend of mine :-) – sclv Mar 30 at 15:43

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 `k-medoids`, and `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):
cluster.setdefault(label, []).append(word)
for label, grp in cluster.items():
print(grp)
``````

yields a result like

``````['apple', 'Doppler', 'applaud', 'append']
['stake', 'steak', 'teak', 'sleek']
['barker', 'baker', 'bismark', 'park']
``````
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