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I'm looking for the fastest algorithm for grouping points on a map into equally sized groups, by distance. The k-means clustering algorithm looks straightforward and promising, but does not produce equally sized groups.

Is there a variation of this algorithm or a different one that allows for an equal count of members for all clusters?

See also: Group n points in k clusters of equal size

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k-means clustering is NP-hard by itself. Maybe you can start changing the distance function till all points fall into equally sized groups, but I am afraid that it is not a convex optimization problem so you are up for some serious computation here. –  Alexei Polkhanov Mar 27 '11 at 21:40
    
Thanks everybody for their good answers. I have meanwhile taken a completely different approach for my initial problem, that doesn't involve clustering anymore. Thus I'm not able to judge which answer should be accepted, I'll just leave this open, hope you don't mind. –  pixelistik May 25 '12 at 9:32

9 Answers 9

This might do the trick: apply Lloyd's algorithm to get k centroids. Sort the centroids by descending size of their associated clusters in an array. For i = 1 through k-1, push the data points in cluster i with minimal distance to any other centroid j (i < jk) off to j and recompute the centroid i (but don't recompute the cluster) until the cluster size is n / k.

The complexity of this postprocessing step is O(k² n lg n).

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Thank you, this sound like a good idea for achieving equally sized groups in a second step. –  pixelistik Mar 27 '11 at 22:52
    
I tried this solution without success, please see my related question stackoverflow.com/questions/8796682/… –  Pierre-David Belanger Jan 9 '12 at 23:52

You can view the distances as defining a weighted graph. Quite a few graph partitioning algorithms are explicitly based on trying to partition the graph vertices into two sets of equal size. This appears in, for example, the Kernighan-Lin algorithm and in spectral graph partitioning using the Laplacian. To get multiple clusters, you can recursively apply the partitioning algorithm; there's a nice discussion of this at the link on spectral graph partitioning.

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The ELKI data mining framework actually has a Tutorial on same-size k-means.

Not that this is a particulary good algorithm, but it's an easy enough k-means variation to write a tutorial for and teach people how to implement their own clustering algorithm variation.

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Consider some form of recursive greedy merge -- each point begins as a singleton cluster and repeatedly merge the closest two such that such a merge doesn't exceed max. size. If you have no choice left but to exceed max size, then locally recluster. This is a form of backtracking hierarchical clustering: http://en.wikipedia.org/wiki/Hierarchical_clustering

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I'm very curious about the "locally recluster" part... –  larsmans Mar 27 '11 at 22:35
    
Looks like a good start here. But, yeah, can you define "locally recluster"? Thank you. –  Pierre-David Belanger Jan 10 '12 at 16:32

May I humbly suggest that you try this project ekmeans.

A Java K-means Clustering implementation with an optional special equal option that apply an equal cardinality constraint on the clusters while remaining as spatially cohesive as possible.

It is yet experimental, so just be aware of the known bugs.

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Added Jan 2012: Better than postprocessing would be to keep cluster sizes roughly the same as they grow.
For example, find for each X the 3 nearest centres, then add X to the one with the best distance - λ clustersize.


A simple greedy postprocess after k-means may be good enough, if your clusters from k-means are roughly equal-sized.
(This approximates an assignment algorithm on the Npt x C distance matrix from k-means.)

One could iterate

diffsizecentres = kmeans( X, centres, ... )
X_centre_distances = scipy.spatial.distance.cdist( X, diffsizecentres )
    # or just the nearest few centres
xtoc = samesizeclusters( X_centre_distances )
samesizecentres = [X[xtoc[c]].mean(axis=0) for c in range(k)]
...

I'd be surprised if iterations changed the centres much, but it'll depend ™.

About how big are your Npoint Ncluster and Ndim ?

#!/usr/bin/env python
from __future__ import division
from operator import itemgetter
import numpy as np

__date__ = "2011-03-28 Mar denis"

def samesizecluster( D ):
    """ in: point-to-cluster-centre distances D, Npt x C
            e.g. from scipy.spatial.distance.cdist
        out: xtoc, X -> C, equal-size clusters
        method: sort all D, greedy
    """
        # could take only the nearest few x-to-C distances
        # add constraints to real assignment algorithm ?
    Npt, C = D.shape
    clustersize = (Npt + C - 1) // C
    xcd = list( np.ndenumerate(D) )  # ((0,0), d00), ((0,1), d01) ...
    xcd.sort( key=itemgetter(1) )
    xtoc = np.ones( Npt, int ) * -1
    nincluster = np.zeros( C, int )
    nall = 0
    for (x,c), d in xcd:
        if xtoc[x] < 0  and  nincluster[c] < clustersize:
            xtoc[x] = c
            nincluster[c] += 1
            nall += 1
            if nall >= Npt:  break
    return xtoc

#...............................................................................
if __name__ == "__main__":
    import random
    import sys
    from scipy.spatial import distance
    # http://docs.scipy.org/doc/scipy/reference/spatial.distance.html

    Npt = 100
    C = 3
    dim = 3
    seed = 1

    exec( "\n".join( sys.argv[1:] ))  # run this.py N= ...
    np.set_printoptions( 2, threshold=200, edgeitems=5, suppress=True )  # .2f
    random.seed(seed)
    np.random.seed(seed)

    X = np.random.uniform( size=(Npt,dim) )
    centres = random.sample( X, C )
    D = distance.cdist( X, centres )
    xtoc = samesizecluster( D )
    print "samesizecluster sizes:", np.bincount(xtoc)
        # Npt=100 C=3 -> 32 34 34
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No big numbers: Npoint=180; NCluster=Npoint/9=20; Ndim=2 (geographical map, 2D) –  pixelistik Mar 29 '11 at 11:37

You want to take a look into space-filling-curve, for example a z-curve or a hilbert-curve. I think of a space-filling-curve to reduce the 2-Dimensional problem to a 1-Dimensional problem. Although the sfc index is only a reorder of the 2-Dimensional data and not a perfect clustering of the data it can be useful when the solution has not to satisfied a perfect cluster and has to be compute fairly fast.

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Could you explain how to use a space filling curve to solve the problem? –  belisarius Mar 28 '11 at 2:39
    
@belisarius: done! –  Phpdna Mar 28 '11 at 17:41

Try this k-means variation:

Initialization:

  • choose k centers from the dataset at random, or even better using kmeans++ strategy
  • for each point, compute the distance to its nearest cluster center, and build a heap for this
  • draw points from the heap, and assign them to the nearest cluster, unless the cluster is already overfull. If so, compute the next nearest cluster center and reinsert into the heap

In the end, you should have a paritioning that satisfies your requirements of the +-1 same number of objects per cluster (make sure the last few clusters also have the right number. The first m clusters should have ceil objects, the remainder exactly floor objects.)

Iteration step:

Requisites: a list for each cluster with "swap proposals" (objects that would prefer to be in a different cluster).

E step: compute the updated cluster centers as in regular k-means

M step: Iterating through all points (either just one, or all in one batch)

Compute nearest cluster center to object / all cluster centers that are closer than the current clusters. If it is a different cluster:

  • If the other cluster is smaller than the current cluster, just move it to the new cluster
  • If there is a swap proposal from the other cluster (or any cluster with a lower distance), swap the two element cluster assignments (if there is more than one offer, choose the one with the largest improvement)
  • otherwise, indicate a swap proposal for the other cluster

The cluster sizes remain invariant (+- the ceil/floor difference), an objects are only moved from one cluster to another as long as it results in an improvement of the estimation. It should therefore converge at some point like k-means. It might be a bit slower (i.e. more iterations) though.

I do not know if this has been published or implemented before. It's just what I would try (if I would try k-means. there are much better clustering algorithms.)

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Recently I needed this myself for a not very large dataset. My answer, although it has a relatively long running time, is guaranteed to converge to a local optimum.

def eqsc(X, K=None, G=None):
    "equal-size clustering based on data exchanges between pairs of clusters"
    from scipy.spatial.distance import pdist, squareform
    from matplotlib import pyplot as plt
    from matplotlib import animation as ani    
    from matplotlib.patches import Polygon   
    from matplotlib.collections import PatchCollection
    def error(K, m, D):
        """return average distances between data in one cluster, averaged over all clusters"""
        E = 0
        for k in range(K):
            i = numpy.where(m == k)[0] # indeces of datapoints belonging to class k
            E += numpy.mean(D[numpy.meshgrid(i,i)])
        return E / K
    numpy.random.seed(0) # repeatability
    N, n = X.shape
    if G is None and K is not None:
        G = N // K # group size
    elif K is None and G is not None:
        K = N // G # number of clusters
    else:
        raise Exception('must specify either K or G')
    D = squareform(pdist(X)) # distance matrix
    m = numpy.random.permutation(N) % K # initial membership
    E = error(K, m, D)
    # visualization
    #FFMpegWriter = ani.writers['ffmpeg']
    #writer = FFMpegWriter(fps=15)
    #fig = plt.figure()
    #with writer.saving(fig, "ec.mp4", 100):
    t = 1
    while True:
        E_p = E
        for a in range(N): # systematically
            for b in range(a):
                m[a], m[b] = m[b], m[a] # exchange membership
                E_t = error(K, m, D)
                if E_t < E:
                    E = E_t
                    print("{}: {}<->{} E={}".format(t, a, b, E))
                    #plt.clf()
                    #for i in range(N):
                        #plt.text(X[i,0], X[i,1], m[i])
                    #writer.grab_frame()
                else:
                    m[a], m[b] = m[b], m[a] # put them back
        if E_p == E:
            break
        t += 1           
    fig, ax = plt.subplots()
    patches = []
    for k in range(K):
        i = numpy.where(m == k)[0] # indeces of datapoints belonging to class k
        x = X[i]        
        patches.append(Polygon(x[:,:2], True)) # how to draw this clock-wise?
        u = numpy.mean(x, 0)
        plt.text(u[0], u[1], k)
    p = PatchCollection(patches, alpha=0.5)        
    ax.add_collection(p)
    plt.show()

if __name__ == "__main__":
    N, n = 100, 2    
    X = numpy.random.rand(N, n)
    eqsc(X, G=3)
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