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I would like to use the output of the density() object as a function (to do many things as derivative, integrate on specific interval, evaluate at specific point,...)

To be clear, let's take an example:

a=c(1,3,10,-5,0,0,2, 1, 3, 8,2, -2)

I would like some transformation of b

f=some_transformation(b) # transformation I don't know
is.function(f) # answer must be "TRUE"

so that I can evaluate the density at any point

f(1.2) # evaluate density at 1.2

compute its derivative

Df=D(body(f), "x") # derivative of f
Df(1.2) # derivative at 1.2

and do other R stuff as if f is a function.

share|improve this question
Isn't the density at any single point by definition 0? – PascalvKooten Sep 5 '13 at 12:23
@Dualinity: No. You may be confusing density with probability, and if that is what you are thinking of then it only applies to continuous distributions. – 42- Sep 5 '13 at 13:12
up vote 3 down vote accepted

You can use approxfun.

a <- c(1,3,10,-5,0,0,2, 1, 3, 8,2, -2)
b <- density(a)
f <- approxfun(b, rule=2)

Since it is not defined by a formula, you cannot use D (symbolic differentiation) to compute its derivative. You can estimate it numerically, though.

df <- function(x) grad(f,x)
curve( f(x),  lwd=3, xlim=c(-10,10) )
curve( df(x), lwd=3, xlim=c(-10,10) )
share|improve this answer
You can do an (approximate, numerical) integral: integrate(f,0,5) for example. – Spacedman Sep 5 '13 at 12:59
Thank you. 'approxfun' return exactly what I want. Because of approximation, I will consider numDeriv. – Manu H Sep 6 '13 at 15:01

D takes an expression, not a function as its first argument. It is for doing symbolic calculus, not finding the gradient of numeric values. You can numerically calculate the derivative of b wrt x using.

with(b, diff(y) / diff(x))

Here's a visualisation of the gradient to give an example of how you might use it.


gradient_data <- with(
      dy_by_dx = diff(y) / diff(x),
      x        = x[-1] + x[-length(x)] / 2

(gradient_plot <- ggplot(gradient_data, aes(x, dy_by_dx)) +

If you want to evaluate the function at any point, then use approx.

with(density(a), approx(x, y, xout = -8:13))

The answer will be more accurate if you increase the n argument to the density function.

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