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Is it possible to specify your own distance function using scikit-learn K-Means Clustering?

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Note that k-means is designed for Euclidean distance. It may stop converging with other distances, when the mean is no longer a best estimation for the cluster "center". – Anony-Mousse Mar 27 '12 at 8:21
why k-means works only with Euclidean distsance? – curious Jan 7 '14 at 12:08
@Anony-Mousse It is incorrect to say that k-means is only designed for Euclidean distance. It can be modified to work with any valid distance metric defined on the observation space. For example, take a look at the article on k-medoids. – Mr. F Oct 15 '14 at 19:04
PAM (aka k-medoids) is a very different algorithm. It's related to k-means but much more expensive. – Anony-Mousse Oct 16 '14 at 8:47
@curious: the mean minimizes squared differences (= squared Euclidean distance). If you want a different distance function, you need to replace the mean with an appropriate center estimation. K-medoids is such an algorithm, but finding the medoid is much more expensive. – Anony-Mousse Oct 16 '14 at 8:48

4 Answers 4

Here's a small kmeans that uses any of the 20-odd distances in scipy.spatial.distance, or a user function.
Comments would be welcome (this has had only one user so far, not enough); in particular, what are your N, dim, k, metric ?

#!/usr/bin/env python
# using any of the 20-odd metrics in scipy.spatial.distance
# kmeanssample 2 pass, first sample sqrt(N)

from __future__ import division
import random
import numpy as np
from scipy.spatial.distance import cdist  # $scipy/spatial/
from scipy.sparse import issparse  # $scipy/sparse/

__date__ = "2011-11-17 Nov denis"
    # X sparse, any cdist metric: real app ?
    # centres get dense rapidly, metrics in high dim hit distance whiteout
    # vs unsupervised / semi-supervised svm

def kmeans( X, centres, delta=.001, maxiter=10, metric="euclidean", p=2, verbose=1 ):
    """ centres, Xtocentre, distances = kmeans( X, initial centres ... )
        X N x dim  may be sparse
        centres k x dim: initial centres, e.g. random.sample( X, k )
        delta: relative error, iterate until the average distance to centres
            is within delta of the previous average distance
        metric: any of the 20-odd in scipy.spatial.distance
            "chebyshev" = max, "cityblock" = L1, "minkowski" with p=
            or a function( Xvec, centrevec ), e.g. Lqmetric below
        p: for minkowski metric -- local mod cdist for 0 < p < 1 too
        verbose: 0 silent, 2 prints running distances
        centres, k x dim
        Xtocentre: each X -> its nearest centre, ints N -> k
        distances, N
    see also: kmeanssample below, class Kmeans below.
    if not issparse(X):
        X = np.asanyarray(X)  # ?
    centres = centres.todense() if issparse(centres) \
        else centres.copy()
    N, dim = X.shape
    k, cdim = centres.shape
    if dim != cdim:
        raise ValueError( "kmeans: X %s and centres %s must have the same number of columns" % (
            X.shape, centres.shape ))
    if verbose:
        print "kmeans: X %s  centres %s  delta=%.2g  maxiter=%d  metric=%s" % (
            X.shape, centres.shape, delta, maxiter, metric)
    allx = np.arange(N)
    prevdist = 0
    for jiter in range( 1, maxiter+1 ):
        D = cdist_sparse( X, centres, metric=metric, p=p )  # |X| x |centres|
        xtoc = D.argmin(axis=1)  # X -> nearest centre
        distances = D[allx,xtoc]
        avdist = distances.mean()  # median ?
        if verbose >= 2:
            print "kmeans: av |X - nearest centre| = %.4g" % avdist
        if (1 - delta) * prevdist <= avdist <= prevdist \
        or jiter == maxiter:
        prevdist = avdist
        for jc in range(k):  # (1 pass in C)
            c = np.where( xtoc == jc )[0]
            if len(c) > 0:
                centres[jc] = X[c].mean( axis=0 )
    if verbose:
        print "kmeans: %d iterations  cluster sizes:" % jiter, np.bincount(xtoc)
    if verbose >= 2:
        r50 = np.zeros(k)
        r90 = np.zeros(k)
        for j in range(k):
            dist = distances[ xtoc == j ]
            if len(dist) > 0:
                r50[j], r90[j] = np.percentile( dist, (50, 90) )
        print "kmeans: cluster 50 % radius", r50.astype(int)
        print "kmeans: cluster 90 % radius", r90.astype(int)
            # scale L1 / dim, L2 / sqrt(dim) ?
    return centres, xtoc, distances

def kmeanssample( X, k, nsample=0, **kwargs ):
    """ 2-pass kmeans, fast for large N:
        1) kmeans a random sample of nsample ~ sqrt(N) from X
        2) full kmeans, starting from those centres
        # merge w kmeans ? mttiw
        # v large N: sample N^1/2, N^1/2 of that
        # seed like sklearn ?
    N, dim = X.shape
    if nsample == 0:
        nsample = max( 2*np.sqrt(N), 10*k )
    Xsample = randomsample( X, int(nsample) )
    pass1centres = randomsample( X, int(k) )
    samplecentres = kmeans( Xsample, pass1centres, **kwargs )[0]
    return kmeans( X, samplecentres, **kwargs )

def cdist_sparse( X, Y, **kwargs ):
    """ -> |X| x |Y| cdist array, any cdist metric
        X or Y may be sparse -- best csr
        # todense row at a time, v slow if both v sparse
    sxy = 2*issparse(X) + issparse(Y)
    if sxy == 0:
        return cdist( X, Y, **kwargs )
    d = np.empty( (X.shape[0], Y.shape[0]), np.float64 )
    if sxy == 2:
        for j, x in enumerate(X):
            d[j] = cdist( x.todense(), Y, **kwargs ) [0]
    elif sxy == 1:
        for k, y in enumerate(Y):
            d[:,k] = cdist( X, y.todense(), **kwargs ) [0]
        for j, x in enumerate(X):
            for k, y in enumerate(Y):
                d[j,k] = cdist( x.todense(), y.todense(), **kwargs ) [0]
    return d

def randomsample( X, n ):
    """ random.sample of the rows of X
        X may be sparse -- best csr
    sampleix = random.sample( xrange( X.shape[0] ), int(n) )
    return X[sampleix]

def nearestcentres( X, centres, metric="euclidean", p=2 ):
    """ each X -> nearest centre, any metric
            euclidean2 (~ withinss) is more sensitive to outliers,
            cityblock (manhattan, L1) less sensitive
    D = cdist( X, centres, metric=metric, p=p )  # |X| x |centres|
    return D.argmin(axis=1)

def Lqmetric( x, y=None, q=.5 ):
    # yes a metric, may increase weight of near matches; see ...
    return (np.abs(x - y) ** q) .mean() if y is not None \
        else (np.abs(x) ** q) .mean()

class Kmeans:
    """ km = Kmeans( X, k= or centres=, ... )
        in: either initial centres= for kmeans
            or k= [nsample=] for kmeanssample
        out: km.centres, km.Xtocentre, km.distances
            for jcentre, J in km:
                clustercentre = centres[jcentre]
                J indexes e.g. X[J], classes[J]
    def __init__( self, X, k=0, centres=None, nsample=0, **kwargs ):
        self.X = X
        if centres is None:
            self.centres, self.Xtocentre, self.distances = kmeanssample(
                X, k=k, nsample=nsample, **kwargs )
            self.centres, self.Xtocentre, self.distances = kmeans(
                X, centres, **kwargs )

    def __iter__(self):
        for jc in range(len(self.centres)):
            yield jc, (self.Xtocentre == jc)

if __name__ == "__main__":
    import random
    import sys
    from time import time

    N = 10000
    dim = 10
    ncluster = 10
    kmsample = 100  # 0: random centres, > 0: kmeanssample
    kmdelta = .001
    kmiter = 10
    metric = "cityblock"  # "chebyshev" = max, "cityblock" L1,  Lqmetric
    seed = 1

    exec( "\n".join( sys.argv[1:] ))  # run N= ...
    np.set_printoptions( 1, threshold=200, edgeitems=5, suppress=True )

    print "N %d  dim %d  ncluster %d  kmsample %d  metric %s" % (
        N, dim, ncluster, kmsample, metric)
    X = np.random.exponential( size=(N,dim) )
        # cf scikits-learn datasets/
    t0 = time()
    if kmsample > 0:
        centres, xtoc, dist = kmeanssample( X, ncluster, nsample=kmsample,
            delta=kmdelta, maxiter=kmiter, metric=metric, verbose=2 )
        randomcentres = randomsample( X, ncluster )
        centres, xtoc, dist = kmeans( X, randomcentres,
            delta=kmdelta, maxiter=kmiter, metric=metric, verbose=2 )
    print "%.0f msec" % ((time() - t0) * 1000)

    # also ~/py/np/kmeans/

Some notes added 26mar 2012:

1) for cosine distance, first normalize all the data vectors to |X| = 1; then

cosinedistance( X, Y ) = 1 - X . Y = Euclidean distance |X - Y|^2 / 2

is fast. For bit vectors, keep the norms separately from the vectors instead of expanding out to floats (although some programs may expand for you). For sparse vectors, say 1 % of N, X . Y should take time O( 2 % N ), space O(N); but I don't know which programs do that.

2) Scikit-learn clustering gives an excellent overview of k-means, mini-batch-k-means ... with code that works on scipy.sparse matrices.

3) Always check cluster sizes after k-means. If you're expecting roughly equal-sized clusters, but they come out [44 37 9 5 5] % ... (sound of head-scratching).

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+1 First of all, thank you for sharing your implementation. I just wanted to confirm that the algorithm works great for my dataset of 900 vectors in a 700 dimensional space. I was just wondering if it is also possible to evaluate the quality of the clusters generated. Can any of the values in your code be reused to compute the cluster quality to aid in selecting the number of optimal clusters? – Legend Jul 11 '11 at 6:10
Legend, you're welcome. (Updated the code to print cluster 50 % / 90 % radius). "Cluster quality" is a largish topic: how many clusters do you have, do you have training samples with known clusters, e.g. from experts ? On number of clusters, see SO how-do-i-determine-k-when-using-k-means-clustering-when-using-k-means-clustering – denis Jul 11 '11 at 11:03
Thank you once again. Actually, I do not have the training samples but am trying to verify the clusters manually after classification (trying to play the role of the domain expert as well). I am performing a document-level classification after applying SVD to some original documents and reducing their dimension. The results seem good but I wasn't sure on how to validate them. For the initial stage, while exploring various cluster validity metrics, I came across Dunn's Index, Elbow method etc. wasn't really sure which one to utilize so thought I will start off with the Elbow method. – Legend Jul 11 '11 at 17:24
And of course, I was also looking at computing the silhouette width to determine the cluster quality but at first look, it seemed quite expensive though I am not sure if I missed something obvious. – Legend Jul 11 '11 at 18:20
Not sure if you faced this but I was trying to use my other example (…) using this code to divide the 10 points into three clusters and it throws an error: ValueError: operands could not be broadcast together with shapes (0) (2) Just thought I will let you know about it as it has something to do with your latest addition. – Legend Jul 11 '11 at 22:39

Unfortunately no: scikit-learn current implementation of k-means only uses Euclidean distances.

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Yes you can use a difference metric function; however, by definition, the k-means clustering algorithm relies on the eucldiean distance from the mean of each cluster.

You could use a different metric, so even though you are still calculating the mean you could use something like the mahalnobis distance.

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+1: Let me emphasize this taking the mean is only appropriate for certain distance functions, such as the Euclidean distance. For other distance functions, you'd need to replace the cluster-center estimation function, too! – Anony-Mousse Mar 27 '12 at 8:20
@Anony-Mousse. What am i supposed to change when i use the cosine distance for instance? – curious Jan 7 '14 at 12:10
I don't know. I havn't seen a proof for convergence with Cosine. I believe it will converge if your data is non-negative and normalized to the unit sphere, because then it's essentially k-means in a different vector space. – Anony-Mousse Jan 7 '14 at 13:59

k-means of Spectral Python allows the use of L1 (Manhattan) distance.

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