First, make some data to use. Here, we will look at the Petal Width of two plant species from the built-in `iris`

dataset.

```
## Some sample data from iris
dat <- droplevels(with(iris, iris[Species %in% c("versicolor", "virginica"), ]))
## make a similar graph
library(ggplot2)
ggplot(dat, aes(Petal.Width, fill=Species)) +
geom_density(alpha=0.5)
```

To find the area of the intersection, you can use `approxfun`

to approximate the function describing the overlap. Then, integrate it the get the area. Since these are density curves, their area is 1 (ish) so the integral will be the percentage overlap.

```
## Get density curves for each species
ps <- lapply(split(dat, dat$Species), function(x) {
dens <- density(x$Petal.Width)
data.frame(x=dens$x, y=dens$y)
})
## Approximate the functions and find intersection
fs <- sapply(ps, function(x) approxfun(x$x, x$y, yleft=0, yright=0))
f <- function(x) fs[[1]](x) - fs[[2]](x) # function to minimize (difference b/w curves)
meet <- uniroot(f, interval=c(1, 2))$root # intersection of the two curves
## Find overlapping x, y values
ps1 <- is.na(cut(ps[[1]]$x, c(-Inf, meet)))
ps2 <- is.na(cut(ps[[2]]$x, c(Inf, meet)))
shared <- rbind(ps[[1]][ps1,], ps[[2]][ps2,])
## Approximate function of intersection
f <- with(shared, approxfun(x, y, yleft=0, yright=0))
## have a look
xs <- seq(0, 3, len=1000)
plot(xs, f(xs), type="l", col="blue", ylim=c(0, 2))
points(ps[[1]], col="red", type="l", lty=2, lwd=2)
points(ps[[2]], col="blue", type="l", lty=2, lwd=2)
polygon(c(xs, rev(xs)), y=c(f(xs), rep(0, length(xs))), col="orange", density=40)
```

```
## Integrate it to get the value
integrate(f, lower=0, upper=3)$value
# [1] 0.1548127
```

`weight`

), then why not just do a t-test? – Chris Watson Jul 22 '15 at 22:13