# How Could One Implement the K-Means++ Algorithm?

I am having trouble fully understanding the K-Means++ algorithm. I am interested exactly how the first `k` centroids are picked, namely the initialization as the rest is like in the original K-Means algorithm.

1. Is the probability function used based on distance or Gaussian?
2. In the same time the most long distant point (From the other centroids) is picked for a new centroid.

I will appreciate a step by step explanation and an example. The one in Wikipedia is not clear enough. Also a very well commented source code would also help. If you are using 6 arrays then please tell us which one is for what.

Interesting question. Thank you for bringing this paper to my attention - K-Means++: The Advantages of Careful Seeding

In simple terms, cluster centers are initially chosen at random from the set of input observation vectors, where the probability of choosing vector `x` is high if `x` is not near any previously chosen centers.

Here is a one-dimensional example. Our observations are [0, 1, 2, 3, 4]. Let the first center, `c1`, be 0. The probability that the next cluster center, `c2`, is x is proportional to `||c1-x||^2`. So, P(c2 = 1) = 1a, P(c2 = 2) = 4a, P(c2 = 3) = 9a, P(c2 = 4) = 16a, where a = 1/(1+4+9+16).

Suppose c2=4. Then, P(c3 = 1) = 1a, P(c3 = 2) = 4a, P(c3 = 3) = 1a, where a = 1/(1+4+1).

I've coded the initialization procedure in Python; I don't know if this helps you.

``````def initialize(X, K):
C = [X]
for k in range(1, K):
D2 = scipy.array([min([scipy.inner(c-x,c-x) for c in C]) for x in X])
probs = D2/D2.sum()
cumprobs = probs.cumsum()
r = scipy.rand()
for j,p in enumerate(cumprobs):
if r < p:
i = j
break
C.append(X[i])
return C
``````

EDIT with clarification: The output of `cumsum` gives us boundaries to partition the interval [0,1]. These partitions have length equal to the probability of the corresponding point being chosen as a center. So then, since `r` is uniformly chosen between [0,1], it will fall into exactly one of these intervals (because of `break`). The `for` loop checks to see which partition `r` is in.

Example:

``````probs = [0.1, 0.2, 0.3, 0.4]
cumprobs = [0.1, 0.3, 0.6, 1.0]
if r < cumprobs:
# this event has probability 0.1
i = 0
elif r < cumprobs:
# this event has probability 0.2
i = 1
elif r < cumprobs:
# this event has probability 0.3
i = 2
elif r < cumprobs:
# this event has probability 0.4
i = 3
``````
• Thank you for your answer. I checked the Python code. – Anton Andreev Mar 29 '11 at 8:50
• So for every point in X we generate a probability. Then cumsum is supposed to put weight on these probabilities. I think the idea is to put more weight to the points with higher probability, so when we do "random centroid select" we choose within them. But how do we know to which points we should put more weight (?) - we haven't sorted the probs array and the cumsum function makes the ones at the end of the array with bigger weight (cumsum definition). – Anton Andreev Mar 29 '11 at 9:46
• I mean that cumsum has specific behavior to accumulate to the right (an array where x1<x2), which might be not what we want - put more weight to the ones with higher probability. We might have points with higher probability in the middle (which will get less weight than the ones at the end). – Anton Andreev Mar 29 '11 at 11:09
• I got it now. :) Thanks! – Anton Andreev Mar 29 '11 at 19:08
• To execute the code I used 'numpy' instead of 'scipy'. Also to get the division right I used 'from future import division', otherwise probs is all [0,0,...]. – Anton Andreev Mar 30 '11 at 9:26

One Liner.

Say we need to select 2 cluster centers, instead of selecting them all randomly{like we do in simple k means}, we will select the first one randomly, then find the points that are farthest to the first center{These points most probably do not belong to the first cluster center as they are far from it} and assign the second cluster center nearby those far points.

I have prepared a full source implementation of k-means++ based on the book "Collective Intelligence" by Toby Segaran and the k-menas++ initialization provided here.

Indeed there are two distance functions here. For the initial centroids a standard one is used based numpy.inner and then for the centroids fixation the Pearson one is used. Maybe the Pearson one can be also be used for the initial centroids. They say it is better.

``````from __future__ import division

lines=[line for line in file(filename)]
rownames=[]
data=[]
for line in lines:
p=line.strip().split(' ') #single space as separator
#print p
# First column in each row is the rowname
rownames.append(p)
# The data for this row is the remainder of the row
data.append([float(x) for x in p[1:]])
#print [float(x) for x in p[1:]]
return rownames,data

from math import sqrt

def pearson(v1,v2):
# Simple sums
sum1=sum(v1)
sum2=sum(v2)

# Sums of the squares
sum1Sq=sum([pow(v,2) for v in v1])
sum2Sq=sum([pow(v,2) for v in v2])

# Sum of the products
pSum=sum([v1[i]*v2[i] for i in range(len(v1))])

# Calculate r (Pearson score)
num=pSum-(sum1*sum2/len(v1))
den=sqrt((sum1Sq-pow(sum1,2)/len(v1))*(sum2Sq-pow(sum2,2)/len(v1)))
if den==0: return 0

return 1.0-num/den

import numpy
from numpy.random import *

def initialize(X, K):
C = [X]
for _ in range(1, K):
#D2 = numpy.array([min([numpy.inner(c-x,c-x) for c in C]) for x in X])
D2 = numpy.array([min([numpy.inner(numpy.array(c)-numpy.array(x),numpy.array(c)-numpy.array(x)) for c in C]) for x in X])
probs = D2/D2.sum()
cumprobs = probs.cumsum()
#print "cumprobs=",cumprobs
r = rand()
#print "r=",r
i=-1
for j,p in enumerate(cumprobs):
if r 0:
for rowid in bestmatches[i]:
for m in range(len(rows[rowid])):
avgs[m]+=rows[rowid][m]
for j in range(len(avgs)):
avgs[j]/=len(bestmatches[i])
clusters[i]=avgs

return bestmatches

kclust = kcluster(data,k=4)

print "Result:"
for c in kclust:
out = ""
for r in c:
out+=rows[r] +' '
print "["+out[:-1]+"]"

print 'done'
``````

data.txt:

``````p1 1 5 6
p2 9 4 3
p3 2 3 1
p4 4 5 6
p5 7 8 9
p6 4 5 4
p7 2 5 6
p8 3 4 5
p9 6 7 8
``````