This has been answered here and partially here.

If you want the y-axis to have frequency counts, then the normal curve needs to be scaled according to the number of observations and the binwidth.

```
# Simulate some data. Individuals' heights in cm.
n <- 1000
mean <- 165
sd <- 6.6
binwidth <- 2
height <- rnorm(n, mean, sd)
qplot(height, geom = "histogram", breaks = seq(130, 200, binwidth),
colour = I("black"), fill = I("white"),
xlab = "Height (cm)", ylab = "Count") +
# Create normal curve, adjusting for number of observations and binwidth
stat_function(
fun = function(x, mean, sd, n, bw){
dnorm(x = x, mean = mean, sd = sd) * n * bw
},
args = c(mean = mean, sd = sd, n = n, bw = binwidth))
```

EDIT

Or, for a more flexible approach that allows for use of facets and draws upon an approach listed here, create a separate dataset containing the data for the normal curves and overlay these.

```
library(plyr)
dd <- data.frame(
predicted = rnorm(720, mean = 2, sd = 2),
state = rep(c("A", "B", "C"), each = 240)
)
binwidth <- 0.5
grid <- with(dd, seq(min(predicted), max(predicted), length = 100))
normaldens <- ddply(dd, "state", function(df) {
data.frame(
predicted = grid,
normal_curve = dnorm(grid, mean(df$predicted), sd(df$predicted)) * length(df$predicted) * binwidth
)
})
ggplot(dd, aes(predicted)) +
geom_histogram(breaks = seq(-3,10, binwidth), colour = "black", fill = "white") +
geom_line(aes(y = normal_curve), data = normaldens, colour = "red") +
facet_wrap(~ state)
```