K-means algorithm variation with equal cluster size
EDIT: like casperOne point it out to me this question is a duplicate. Anyways here is a more generalized question that cover this one: http://stats.stackexchange.com/questions/8744/clustering-procedure-where-each-cluster-has-an-equal-number-of-points
In a project I need to group n points (x,y) in k clusters of equal size (n / k). Where x and y are double floating numbers, n can range from 100 to 10000 and k can range from 2 to 100. Also k is known before the algorithm runs.
I started to resolve the problem by using the http://en.wikipedia.org/wiki/K-means_clustering algorithm, which work great and fast to produce exactly k clusters of roughly the same size.
But my problem is this, K-means produce clusters of roughly the same size, where I need the clusters to be exactly the same size (or to be more precise: I need them to have a size between floor(n / k) and ceil(n / k)).
Before you point it out to me, yes I tried the first answer here K-means algorithm variation with equal cluster size, which sounds like a good idea.
The main idea is to post process the array of cluster produce by K-means. From the biggest cluster up to the smallest. We reduce the size of the clusters that have more than n / k members by moving extra points to an other nearest cluster. Leaving alone the clusters that are already reduced.
Here is the pseudo code I implemented:
n is the number of point k is the number of cluster m = n / k (the ideal cluster size) c is the array of cluster after K-means c' = c sorted by size in descending order for each cluster i in c' where i = 1 to k - 1 n = size of cluster i - m (the number of point to move) loop n times find a point p in cluster i with minimal distance to a cluster j in c' where j > i move point p from cluster i to cluster j end loop recalculate centroids end for each
The problem with this algorithm is that near the end of the process (when i come close to k), we have to choose a cluster j in c' (where j > i because we need to leave alone the clusters already processed), but this cluster j we found can be far from cluster i, thus breaking the concept of cluster.
Is there a post K-means algorithm or a K-means variant that can meet my requirements, or am I wrong from the beginning and I need to find an other clustering algorithm?
PS: I do not mind to implement the solution myself, but it would be great if I can use a library, and ideally in JAVA.