# Heston Simulation Monte Carlo: Slow R code [duplicate]

I need to simulate the stock price, that follows stochastic volatility process (Heston Model). I already asked, how to speed up my loops, but for this case I´m not able to use some tips due to the V[i-1] dependence.

Basically the code is: V is the volatility of the stock and S is the stock price. And: a,b,c... constants.

Here is the code:

``````V[1] <- 0.04
S[1] <- 40
U <- matrix(NA, nrow=100000, ncol=200, byrow=TRUE)

### Function ###
Inv.Phi <- function(y){
if (y <= p) {0} else {log(1-p)}
}

### Simulation ####
for(j in 1:100000){
for(i in 2:200){
m <- V[i-1] * c
n <- V[i-1] * d
phi <- n/m

if(phi <= 1.5){
Z <- rnorm(1)
V[i] <- rnorm(1) * e
K <- V[i-1] * f
}else{
p <- (phi-1) / (phi+1)
u <- runif(1)
V[i] <- Inv.Phi(u)
K <- V[i-1] * g
}
S[i] <- S[i-1] * exp(K * V[i-1]) * exp(V[i] * rnorm(1))
}
U[j,] = S
}
``````

Any suggestion to speed up this process! I known, I´m using a lot of bad things for R, but I couldn´t figure out a better solution.

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## marked as duplicate by Paul Hiemstra, Dirk Eddelbuettel, plannapus, ben75, GuruMar 23 '13 at 12:26

How exactly is this different than your other question? stackoverflow.com/questions/15534270/… –  Paul Hiemstra Mar 22 '13 at 21:03
Is anyone else getting the suspicion we are asked to do this person's business school homework? –  BondedDust Mar 22 '13 at 22:20
If it were a Heston model (it looks different: there is a threshold in your model), you could try `sde::sde.sim` to simulate the volatility, and vectorize your code, as in your previous question, to compute the prices. If this is not sufficient, you can try to rewrite the loop in C/C++, e.g., with Rcpp. –  Vincent Zoonekynd Mar 22 '13 at 22:34
As I see I wasn´t supposed to open another question. I apologize for that. But I´m not able to put inside the matrix the if else and the initial price. And also due to the fact that the stock price depends also to another stochastic factor. Anyway sorry for the inconvenient –  PereMkB Mar 22 '13 at 22:53
I'm sure it would be an interesting exercise to speed up/fix your homework, bu as it stands we can't. You haven't defined `c` or `d` or `e` or `f` and indeed `g`! –  Simon O'Hanlon Mar 22 '13 at 22:54

You will probably speed things up a lot if you get rid of the outer loop and construct an entire column of your matrix at once:

``````nsim <- 1e5
nt <- 200
U <- matrix(NA, nrow=nsim, ncol=200, byrow=TRUE)
V_last <- V <- rep(0.04, nsim)
U[,1] <- 40

Inv.phi <- function(y,p) ifelse (y <= p, 0, log(1-p))
for(i in 2:nt) {
m <- V_last * c
n <- V_last * d
phi <- n/m ## ??? as currently stated this is just a constant d/c ??
## presumably there is a typo somewhere??
bt <- (phi<=1.5) ## below-threshold
V[bt] <- rnorm(length(bt)) * e
V[!bt] <- Inv.phi(runif(length(!bt)), (phi[!bt]-1) / (phi[!bt]+1))
K <- V_last*ifelse(bt,f,g)
U[,i] <- U[,i-1] * exp(K * V_last) * exp(V * rnorm(nsim))
V_last <- V
}
``````

I think this works but can't test it because you haven't given a reproducible example ...

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thanks a lot for your attention! When I was shrinking the code, I forgot to delete that “Z”. Yes, d and c are constants. I´ve just tried your idea and works much, much faster than with both loops. However, there is a warning regarding the if/else. It warns that the size of phi>1, so it is using only the first one. When I´m running the complete simulation, the expected answer (for an example) is approximately 4.47, but now is resulting near 4,58. I´ll try to find out what is happening. Thanks a lot again –  PereMkB Mar 23 '13 at 9:22
fixed to allow for vector `phi`. The issue is not that `c` and `d` are constants, it's that `phi = (V_last*d)/(V_last*c) = d/c`, so `phi` will also always be a constant ... –  Ben Bolker Mar 23 '13 at 14:19