Stack Overflow is a community of 4.7 million programmers, just like you, helping each other.

Join them; it only takes a minute:

Sign up
Join the Stack Overflow community to:
  1. Ask programming questions
  2. Answer and help your peers
  3. Get recognized for your expertise

I wonder if Triangle inequality is necessary for the distance measure used in kmeans.

share|improve this question
up vote 3 down vote accepted

k-means is designed for Euclidean distance, which happens to satisfy triangle inequality.

Using other distance functions is risky, as it may stop converging. The reason however is not the triangle inequality, but the mean might not minimize the distance function. (The arithmetic mean minimizes the sum-of-squares, not arbitrary distances!)

There are faster methods for k-means that exploit the triangle inequality to avoid recomputations. But if you stick to classic MacQueen or Lloyd k-means, then you do not need the triangle inequality.

Just be careful with using other distance functions to not run into an infinite loop. You need to prove that the mean minimizes your distances to the cluster centers. If you cannot prove this, it may fail to converge, as the objective function no longer decreases monotonically! So you really should try to prove convergence for your distance function!

share|improve this answer
My goal is to create clusters that have minimum number of 1 bits in all of their members (I need storage space for each 1 bit). I defined the center as Or() of all members and used the |Or(x,y)| as distance function. Currently I use linkage algorithm to create hierarchical clusters instead of using kmeans and that works great – Masood_mj Jul 18 '12 at 6:19
@Anony-Mousse: Do you have a reference for the requirement that the mean must be a minimum variance estimator? I have read a fair share of ML textbooks (e.g. Bishop 2007, Alpaydin 2009), but I have never seen a requirement like that. – stackoverflowuser2010 Sep 14 '15 at 17:34
@stackoverflowuser2010 The mean is the least-squares estimator of location, as proven by Gauss around 1800. That is not a requirement, but a fact. The need to use a consistent criterion in both steps arises from the convergence proof. But did any of these textbooks discuss convergence? (I've improved the wording above, to make it easier to understand.) – Anony-Mousse Sep 14 '15 at 17:39
Unfortunately, ML textbooks tend to be really shallow on non-supervised methods. – Anony-Mousse Sep 14 '15 at 17:44

Well, classical kmeans is defined on Euclidean space with L2 distance, so you get triangle inequality automatically from that (triangle inequality is part of how a distance/metric is defined). If you are using a non-euclidean metric, you would need to define what is the meaning of the "mean", amongst other things.

If you don't have triangle inequality, it means that two points could be very far from each other, but both can be close to a third point. You need to think how you would like to interpret this case.

Having said all that, I have in the past used average linkage hierarchical clustering with a distance measure that did not fulfill triangle inequality amongst other things, and it worked great for my needs.

share|improve this answer
Thanks. I am working on binary data and define the mean as Or() of bits of points in a cluster. I want to use d(A,B)=|Xor(A,B)|/|And(A,B)| which shows the cost of adding a point to a cluster over the benefit. However it does not satisfy the property. I first considered Jaccord distance but its meaning is different. – Masood_mj Jul 16 '12 at 18:31
I am not sure what your metric is trying to achieve, but kmeans is really defined for L2 (euclidean) distance - other methods like UPGMA allow different metrics more naturally. Regarding a metric, it really depends what your goal is, but how about Hamming distance? It fulfills the triangle inequality. – Bitwise Jul 16 '12 at 20:47

Your Answer


By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.