Here, we illustrate optimal
univariate clustering function Ckmeans.1d.dp
. It uses a
given number of clusters k, or
estimates k if a range is
provided. If k is unspecified,
a default range from 1 to 9 is used. It can also perform optimal
weighted clustering when a non-negative weight vector is specified as
input. Weighted clustering can be used to analyze signals such as time
series data, spectral data, genetic or epigenetic events along a
chromosome.
Cluster data generated from a Gaussian mixture model of three components.
The number of clusters is provided.
Cluster data generated from a Gaussian mixture model of three components. The number of clusters is determined by Bayesian information criterion:
x <- c(rnorm(50, mean=-1, sd=0.3), rnorm(50, mean=1, sd=1), rnorm(50, mean=2, sd=0.4))
# Divide x into k clusters, k automatically selected (default: 1~9)
result <- Ckmeans.1d.dp(x)
k <- max(result$cluster)
colors <- brewer.pal(k, "Dark2")
## Warning in brewer.pal(k, "Dark2"): minimal value for n is 3, returning requested palette with 3 different levels
plot(x, col=colors[result$cluster], pch=result$cluster, cex=1.5,
main="Optimal univariate clustering with k estimated",
sub=paste("Number of clusters is estimated to be", k))
abline(h=result$centers, col=colors, lty="dashed", lwd=2)
legend("topleft", paste("Cluster", 1:k), col=colors, pch=1:k, cex=1, bty="n")
We segment a time course to identify peaks using weighted clustering. The input data is the time stamp of obtaining each intensity measurement; the weight is the signal intensity.
n <- 160
t <- seq(0, 2*pi*2, length=n)
n1 <- 1:(n/2)
n2 <- (max(n1)+1):n
y1 <- abs(sin(1.5*t[n1]) + 0.1*rnorm(length(n1)))
y2 <- abs(sin(0.5*t[n2]) + 0.1*rnorm(length(n2)))
y <- c(y1, y2)
w <- y^8 # stress the peaks
res <- Ckmeans.1d.dp(t, k=c(1:10), w)
k <- max(res$cluster)
colors <- brewer.pal(k, "Set1")
plot(res, col.clusters = colors)
grid()
plot(t, w, main = "Time course clustering / peak calling",
col=colors[res$cluster], pch=res$cluster, type="h",
xlab="Time t", ylab="Transformed intensity w")
grid()
abline(v=res$centers, col="gray", lty="dashed")
text(res$centers, max(w) * .95, cex=0.75, font=2,
paste(round(res$size / sum(res$size) * 100), "/ 100"))
It is often desirable to visualize boundaries between consecutive
clusters. The ahist()
function offers several ways to
estimate cluster boundaries. The simplest is to use the midpoint between
the two closest points in two consecutive clusters, as illustrated in
the code below.
x <- c(7, 4, 1, 8, 15, 22, -1)
k <- 3
ckm <- Ckmeans.1d.dp(x, k=k)
midpoints <- ahist(ckm, style="midpoints", data=x, plot=FALSE)$breaks[2:k]
colors <- brewer.pal(k, "Set2")
plot(ckm, col.clusters = colors, lwd=5,
main="Midpoints as cluster boundaries")
abline(v=midpoints, col="RoyalBlue", lwd=3, lty=2)
legend("topright", "Midpoints", lwd=3, lty=2, col="RoyalBlue")