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I'm trying to implement the monte carlo method in R to find the approximate value for the following double integral:

enter image description here

I have the following code:

mean.estimated <- function(nvals) {
    X <- runif(nvals)
    Y <- runif(nvals)
    sum(exp((2*X + 3*Y)^5))/ nvals

monte.carlo <- function(nreps,nvals) {
    estimates <- NULL
    for (i in 1:nreps){
        estimates[i] <- mean.estimated(nvals)

simvalues <- monte.carlo(200,2000)

But it only produces Inf values. What am i doing wrong?

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1 Answer 1

With X and Y bounded between 0 and 1, we have that 2*X + 3*Y takes a value between 0 and 5.

When it is the case that 2*X + 3*Y exceeds about 3.72, we have that exp((2*X + 3*Y)^5) is infinite:

> exp((3.72)^5)
[1] Inf

If any one value in the sum is infinite, the sum is infinite. I am not going to compute the odds here, but it is somewhat unlikely that of 2000 samples, every one will have 2*X + 3*Y not exceeding ~3.72. So unlikely that you get Inf for every sample.

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@ Matthew Lundberg So, is this problem impossible to solve via the Monte Carlo method? –  DaveQuinn Dec 2 '13 at 0:08
As stated, it is impossible to compute numerically, as a large part of the domain will cause exp to return infinity. –  Matthew Lundberg Dec 2 '13 at 0:10
I tried even with a small number of trials and repetitions, 2 and 1 respectively, and the generated numbers are way too large. I'm sorry for insisting on the matter but this was given to me as an assignment. Should i turn in the assignment as impossible to solve @Matthew Lundberg? –  DaveQuinn Dec 2 '13 at 0:32
The Wolfram site returns this as the indefinite integral of e^x^5: integral integral e^(x^5) dx dx = c_1 x+c_2+((-x^5)^(4/5) Gamma(1/5, -x^5))/(5 x^3)+(x^2 Gamma(2/5, -x^5))/(5 (-x^5)^(2/5)) –  BondedDust Dec 2 '13 at 0:46

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