# Getting values from kernel density estimation in R

I am trying to get density estimates for the log of stock prices in R. I know I can plot it using `plot(density(x))`. However, I actually want values for the function.

I'm trying to implement the kernel density estimation formula. Here's what I have so far:

``````a <- read.csv("boi_new.csv", header=FALSE)
S = a[,3] # takes column of increments in stock prices
dS=S[!is.na(S)] # omits first empty field

N = length(dS)                  # Sample size
rseed = 0                       # Random seed
x = rep(c(1:5),N/5)             # Inputted data

set.seed(rseed)   # Sets random seed for reproducibility

QL <- function(dS){
h = density(dS)\$bandwidth
r = log(dS^2)
f = 0*x
for(i in 1:N){
f[i] = 1/(N*h) * sum(dnorm((x-r[i])/h))
}
return(f)
}

QL(dS)
``````

Any help would be much appreciated. Been at this for days!

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What is your question –  Dason Jan 27 '13 at 20:09
@Dason I was trying to find values for density function. –  Ruth O'Brien Jan 27 '13 at 20:22

You can pull the values directly from the `density` function:

``````x = rnorm(100)
d = density(x, from=-5, to = 5, n = 1000)
d\$x
d\$y
``````

Alternatively, if you really want to write your own kernel density function, here's some code to get you started:

1. Set the points `z` and `x` range:

``````z = c(-2, -1, 2)
x = seq(-5, 5, 0.01)
``````
2. Now we'll add the points to a graph

``````plot(0, 0, xlim=c(-5, 5), ylim=c(-0.02, 0.8),
pch=NA, ylab="", xlab="z")
for(i in 1:length(z)) {
points(z[i], 0, pch="X", col=2)
}
abline(h=0)
``````
3. Put Normal density's around each point:

``````## Now we combine the kernels,
x_total = numeric(length(x))
for(i in 1:length(x_total)) {
for(j in 1:length(z)) {
x_total[i] = x_total[i] +
dnorm(x[i], z[j], sd=1)
}
}
``````

and add the curves to the plot:

``````lines(x, x_total, col=4, lty=2)
``````
4. Finally, calculate the complete estimate:

``````## Just as a histogram is the sum of the boxes,
## the kernel density estimate is just the sum of the bumps.
## All that's left to do, is ensure that the estimate has the
## correct area, i.e. in this case we divide by \$n=3\$:

plot(x, x_total/3,
xlim=c(-5, 5), ylim=c(-0.02, 0.8),
ylab="", xlab="z", type="l")
abline(h=0)
``````

This corresponds to

``````density(z, adjust=1, bw=1)
``````

The plots above give:

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Thank you soooo much! You are a lifesaver. Been staring at this for days. Can't thank you enough! –  Ruth O'Brien Jan 27 '13 at 20:15