# How to calculate BIC for k-means clustering in R

I've been using k-means to cluster my data in R but I'd like to be able to assess the fit vs. model complexity of my clustering using Baysiean Information Criterion (BIC) and AIC. Currently the code I've been using in R is:

KClData <- kmeans(Data, centers=2, nstart= 100)


But I'd like to be able to extract the BIC and Log Likelihood. Any help would be greatly appreciated!

• Function Mclust in package mclust might be of interest. Apr 5, 2013 at 17:45
• Roland, thanks for the tip! I'm actually trying to compare the results of k-means to Mclust outputs which is why I'd like to use the BIC from my k-means clustering to GMM that Mclust uses. Apr 5, 2013 at 17:50
• I am not an expert, but think that k-means is not a maximum likelihood algorithm. Are you sure that AIC and BIC are applicable? Apr 5, 2013 at 17:58
• It does have a log Likelihood associated with it but I'm having trouble finding it and implementing it in R. Apr 6, 2013 at 19:53
• See a similar question on a statistician community stats.stackexchange.com/q/55147/3277 Jun 30, 2016 at 9:34

For anyone else landing here, there's a method proposed by Sherry Towers at http://sherrytowers.com/2013/10/24/k-means-clustering/, which uses output from stats::kmeans. I quote:

The AIC can be calculated with the following function:

kmeansAIC = function(fit){

m = ncol(fit$centers) n = length(fit$cluster)
k = nrow(fit$centers) D = fit$tot.withinss
return(D + 2*m*k)
}


From the help for stats::AIC, you can also see that the BIC can be calculated in a similar way to the AIC. An easy way to get the BIC is to replace the return() in the above function, with this:

return(data.frame(AIC = D + 2*m*k,
BIC = D + log(n)*m*k))


So you would use this as follows:

fit <- kmeans(x = data,centers = 6)
kmeansAIC(fit)

• I have used your methods, but the BIC value of the kmeans results always monotone decreasing with the cluster number increasing. Please look the posts: stats.stackexchange.com/questions/55147/… Nov 24, 2015 at 4:21
• Taking a wild guess, I'd say there's an error somewhere. Nov 24, 2015 at 4:24
• Thank you Any Clifton, I have tested the BIC with higher K number, when K reach 155 the BIC come to the smallest value. Originally, I have only tested the K with maximum 50. Nov 24, 2015 at 7:53
• @pengchy: you may be interested in this answer about finding optimum values of k: stackoverflow.com/a/18047359/2514568 Nov 24, 2015 at 10:17
• Hi Andy Clifton, thank you for the information. It is very helpful. Nov 24, 2015 at 23:30

To compute BIC, just add .5*k*d*log(n) (where k is the number of means, d is the length of a vector in your dataset, and n is the number of data points) to the standard k-means error function.

The standard k-means penalty is \sum_n (m_k(n)-x_n)^2, where m_k(n) is the mean associated with the nth data point. This penalty can be interpreted as a log probability, so BIC is perfectly valid.

BIC just adds an additional penalty term to the k-means error proportional to k.

• I don't think the k-means penalty \sum_n (m_k(n) - x_n)^2 (or the negative of that) is the log-likelihood. The log-likelihood should have 3 more terms: -n*log(K), -0.5*n*d*log(2*pi) and -n*d*log(\sigma), where \sigma is the common std for all Gaussians. Also, the "k" in the BIC formula is not the number of clusters, it is the number of free parameters in the mixture Gaussian model, so k should be: k = K-1 + 1 + K*d = K*(d+1). Here I am using lower k for the BIC parameter term, and capital K as the number of means/clusters. Jun 14, 2015 at 14:39
• K-1 is K-1 number of weights for the Gaussians, since the weights add up to 1, the dof is K-1. 1 for the one common std for all Gaussians. And K*d is the number of parameters for the coordinates of the cluster centers. Jun 14, 2015 at 14:40
• Are there any weights in k-means? I think not.. So why do we need K-1? Jun 30, 2016 at 9:21

Just to add to what user1149913 said (I don't have enough reputation to comment), since you're using the kmeans function in R, \sum_n (m_k(n)-x_n)^2 is already calculated for you as KClData$tot.withinss. Rather than reimplementing AIC or BIC, we can define a log-likelihood function for kmeans objects; this will then get used by the BIC function in the stats package. logLik.kmeans <- function(object) structure( -object$tot.withinss/2,
df = nrow(object$centers)*ncol(object$centers),
nobs = length(object$cluster) )  Then to use it, call BIC as normal. For example: example(kmeans, local=FALSE) BIC(cl) # [1] 26.22842084  This method will be provided in the next release of the stackoverflow package. • Waiting for the new version of stackoverflow, current version 0.1.2 hasn't implemented this function. Nov 24, 2015 at 3:26 • @pengchy the github version has it, I'll submit to cran when I get the chance. Nov 26, 2015 at 3:11 • you are sign inverted. You need a minus sign. Jan 15, 2018 at 19:39 A function qualityCriterion::longitudinalData can calculate BIC and AIC for k-means cluster. It first calculates the likelihood for each cluster centres on every individual before merging together with weights on cluster size. The sd of the normal density function is based on RSS. While the original code gives -BIC instead of BIC, I adopted the code for BIC: qualityCriterion <- function (traj, clusters) { if (nrow(traj) != length(clusters)) { stop("[qualityCriterion] the cluster and the number of trajectory should be the same.") } clusters <- as.integer(clusters) nbIndiv <- nrow(traj) nbTime <- ncol(traj) nbClusters <- length(unique(clusters)) # Cluster frequency preProba <- as.numeric(table(clusters)) preProba <- preProba / sum(preProba) # Centers as cluster means moy <- matrix(, nbClusters, nbTime) for (i in 1:nbClusters) { moy[i, ] <- apply(traj[as.numeric(clusters) == i, , drop = FALSE], 2, meanNA) } # sd of residuals ecart <- sqrt(mean(as.numeric(traj - moy[clusters, ])^2, na.rm=TRUE)) # likelihood vraisIndivXcluster <- matrix(, nbIndiv, nbClusters) for (i in 1:nbClusters) { vraisIndivXcluster[, i] <- preProba[i] * apply(dnorm(t(traj), moy[i, ], ecart), 2, prod, na.rm = TRUE ) } vraisIndivXcluster <- apply(vraisIndivXcluster, 1, sum) logVraisemblance <- sum(log(vraisIndivXcluster)) nbParam <- nbClusters * nbTime + 1 # cluster centers and sd #BIC <- -2 * logVraisemblance + nbParam * log(nbIndiv) # BIC for time series BIC2 <- -2 * logVraisemblance + nbParam * log(nbIndiv * nbTime) # BIC for independent columns AIC <- 2 * nbParam - 2 * logVraisemblance #AICc <- AIC + (2 * nbParam * (nbParam + 1)) / (nbIndiv - nbParam - 1) # AICc for time series #AICc2 <- AIC + (2 * nbParam * (nbParam + 1)) / (nbIndiv * nbTime - nbParam - 1) # AICc for independent columns return(list(criters = c(BIC2 = BIC2, AIC = AIC))) }  Example of 100 individuals, each with 2 data points, forming 3 clusters: set.seed(1) dat <- matrix(rnorm(100 * 2), nrow = 100, ncol = 2) # data of 100 individuals dat[34:66,] <- dat[34:66,] + 4 dat[67:100,] <- dat[67:100,] + 8 plot(dat[,1], dat[,2]) # 3 cluster centers at (0,0), (4,4), (8,8)  As expected, minimum BIC at k = 3 clusters: # k-means with k = 2:5 clusters_2 <- kmeans(dat, centers = 2) clusters_3 <- kmeans(dat, centers = 3) clusters_4 <- kmeans(dat, centers = 4) clusters_5 <- kmeans(dat, centers = 5) BIC <- c(qualityCriterion(dat, rep(1, nrow(dat)))$criters["BIC2"],
qualityCriterion(dat, clusters_2$cluster)$criters["BIC2"],
qualityCriterion(dat, clusters_3$cluster)$criters["BIC2"],
qualityCriterion(dat, clusters_4$cluster)$criters["BIC2"],
qualityCriterion(dat, clusters_5$cluster)$criters["BIC2"]
)

plot(1:5, BIC, xlab = "k", ylab = "BIC")
lines(1:5, BIC)