# Simulate data from (non-standard) density function

I want to simulate data from a non-standard density function. I already found the following link (R: How do I best simulate an arbitrary univariate random variate using its probability function?). However, this gives weird results. Somehow, this cumulative density function ( cdf() ) does not work well. From some values, it gives very strange results. For example, take a look at the following code:

``````density=function(x)(25*200.7341^25/x^26*exp(-(200.7341/x)^25))
cdf<-function(x) integrate(density,1,x)[[1]]

cdf(9701)
[1] 1

cdf(9702)
[1] 6.33897e-05
``````

So my question, how can I create a "good" CDF function? Or more directly, how can I simulate data from a PDF?

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As pointed out by @pjs we can use Rejection sampling (check the wiki for details).

Here is one implementation of this approach.

The most important step is to find a distribution g from which we can sample and from which it exists M such that M * g > f for all point

``````f <- function(x) (25 * 200.7341^25 / x^26 * exp(-(200.7341/x)^25))
g <- function(x) dnorm(x, mean = 200.7341, sd = 40)
M <- 5
curve(f, 0, 500)
curve(M * g(x), 0, 500, add = TRUE, lty = "dashed")
``````

Now, we can execute the algorithm

``````k <- 1
count <- 0
res <- vector(mode = "numeric", length = 1000)
while(k < 1001) {
z <- rnorm(n = 1, mean = 200.7341, sd = 40)
R <- f(z) / M * g(z)
if (R > runif(1)) {
res[k] <- z
k  <- k + 1
}
count <- count + 1
}

(accept_rate <- (k / count) * 100)
## [1] 0.20773

require(MASS) ## for truehist
truehist(res)
curve(f, 0, 250, add = TRUE)
``````

The acceptance rate is poor so may be you can try do find a better envelope function or use a Metropolis Hasting algorithm.

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Thanks! This worked perfectly! Although indeed a bit slow, it is great for what I want to do. –  Sjoerd Glaser Apr 22 at 7:30

If the integration interval is very large, the peak of the density is very difficult to find: `integrate` can easily miss it, and think that the function you are integrating is (almost) zero everywhere.

If you know where the peak is, you can cut the integral into three: around the peak, before, and after.

``````# Density
A <- 200.7341
f <- function(x) 25*A^25 / x^26 * exp( -(A/x)^25 )
a <- 150
b <- 400

# Numeric integration
F1 <- function(x) {
if( x < a )      integrate(f, 1, x)[[1]]
else if( x < b ) integrate(f, 1, a)[[1]] + integrate(f, a, x)[[1]]
else             integrate(f, 1, a)[[1]] + integrate(f, a, b)[[1]] + integrate(f, b, x)[[1]]
}

# Compare with the actual values
F2 <- function(x) exp( -(A/x)^25 )
F1(200); F2(200)
F1(1e4); F2(1e4)
F1(1e5); F2(1e5) # Imprecise if b is too low...
``````

After checking that your interval is sufficiently large, you can remove the "before" and "after" intervals: their contribution is zero.

``````F1 <- function(x) {
if( x < a )      0
else if( x < b ) integrate(f, a, x)[[1]]
else             1
}
``````
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