# Option Pricing with volatility following a Garch process by use of Monte-Carlo Simulations

``````>   Name    Date    Close   CP  ttmDaysW    ttm Strike  Fut Wibor   lambda  omega   alpha   beta    sigma
1   OW20C1330   2011-01-19  0.60    c   42  0.1673307   3300    2768    0.0425  0.03985676  1.205098e-06    0.05403404  0.9426635   0.010935144
2   OW20C1330   2011-02-16  0.21    c   22  0.0876494   3300    2703    0.0435  0.03285167  5.852091e-07    0.05208226  0.9462142   0.008209948
3   OW20C2150   2011-12-08  745.65  c   71  0.2828685   1500    2233    0.0499  0.05490974  1.213260e-06    0.06837361  0.9296792   0.018583414
4   OW20C2150   2011-12-09  720.80  c   70  0.2788845   1500    2262    0.0499  0.05119041  1.212956e-06    0.06813476  0.9299286   0.019143222
``````

Hi, I created the above dataframe in R which has above 20000 rows. I wrote a code to compute theoretical prices of Options assuming that volatility follow a GARCH(1,1) process. The code works fine but is VERY sluggish. I wonder weather there is any chance to speed it up or Vectorize? I've tried to work it out, but I failed as a beginning R user.Computation is done by Monte Caro Simulation. OW is my Data.Frame

``````#Monte Carlo Garch(1,1)
nsim=10000
for (i in 1:nrow(OW)){
iopt<-ifelse(OW\$CP[i]=="c",1,-1)
sum=0
for (j in 1:nsim){
Sigma2t<-(OW\$sigma[i])^2
Eps<-rnorm(1)*OW\$sigma[i]

sumSigma2t=0
sumEps=0

for (k in 1:OW\$ttmDaysW[i]){
Sigma2t= OW\$omega[i] +OW\$alpha[i]*(Eps-OW\$lambda[i]*sqrt(Sigma2t))^2+OW\$beta[i]*Sigma2t
Eps <- rnorm(1)*sqrt(Sigma2t)

sumEps=sumEps+Eps
sumSigma2t = sumSigma2t + Sigma2t

}
Ft<-OW\$Fut[i]*exp(-0.5*sumSigma2t+sumEps)
payoff <- max(c(iopt * (Ft - OW\$Strike[i]), 0))
sum<-sum+payoff
}
OW\$G[i] = exp(-OW\$Wibor[i] * OW\$ttm[i]) * sum / nsim
}
``````

I have found only this help on my question:Simulation of GARCH in R

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Generally, indexing data frames (which you do a lot), takes a lot of time. Consider vectorizing this. Especially since you are computing all those OW\$something[i]'s more than 200 million times (since all the nested for loops) where they actually only have to be called 10,000 times (nsim times). See if this runs any quicker.

``````nsim=10000
for (i in 1:nrow(OW)){
iopt<-ifelse(OW\$CP[i]=="c",1,-1)
sum=0
OWSigma <- OW\$sigma[i]
OWOmega <- OW\$omega[i]
OWAlpha <- OW\$alpha[i]
OWLambda <- OW\$lambda[i]
OWBeta <- OW\$beta[i]
OWFut <- OW\$Fut[i]
OWStrike <- OW\$Strike[i]
OWTtmDaysW <- OW\$ttmDaysW[i]
for (j in 1:nsim){
Sigma2t<-(OWSigma)^2
Eps<-rnorm(1)*OWSigma

sumSigma2t=0
sumEps=0

for (k in 1:OWTtmDaysW){
Sigma2t= OWOmega +OWAlpha*(Eps-OWLambda*sqrt(Sigma2t))^2+OWBeta*Sigma2t
Eps <- rnorm(1)*sqrt(Sigma2t)

sumEps=sumEps+Eps
sumSigma2t = sumSigma2t + Sigma2t

}
Ft<-OWFutexp(-0.5*sumSigma2t+sumEps)
payoff <- max(c(iopt * (Ft - OWStrike, 0))
sum<-sum+payoff
}
OW\$G[i] = exp(-OW\$Wibor[i] * OW\$ttm[i]) * sum / nsim
}
``````
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Thanks. It speeded up the code quite well. As you said, i'm doing my best at vectorizing this. – user2064822 Feb 13 '13 at 10:06
then you can also click "accept this answer" if this solved your problem ;-) – Gx1sptDTDa Feb 13 '13 at 13:50
i would accept but i stil expect a vectorized solution as the one that is satisfactory to me, because this takes over a week to get my results ( i have couple similar models to compute). Bus still very thankful for what you have done to me :) – user2064822 Feb 15 '13 at 12:32

It's vectorized solution to my question!

``````#Monte Carlo Garch(1,1)
N=10000
system.time(for (i in 1:nrow(OW)){
iopt<-ifelse(OW\$CP[i]=="c",1,-1)
h0<- (OW\$sigma[i])^2
omega <- OW\$omega[i]
alpha1 <- OW\$alpha[i]
lambda <- OW\$lambda[i]
beta1 <- OW\$beta[i]
Fu <- OW\$Fut[i]
Str <- OW\$Strike[i]
horizon <- OW\$ttmDaysW[i]
Wibor<-OW\$Wibor[i]
ttm<-OW\$ttm[i]
ret <- et <- ht <- matrix(NA, nc = horizon, nr = N)
zt  <- matrix(rnorm(N * horizon, 0, 1), nc = horizon)
hB<-matrix(rep(h0,N),nr=N)
eB<-matrix(rnorm(N, 0, 1), nc=1) * sqrt(hB)
Fut<-matrix(rep(Fu,N),nr=N)
Strike<-matrix(rep(Str,N),nr=N)
for(j in 1:horizon){
ifelse(j>1,
ht[, j ] <- omega + alpha1 * (et[, j-1]-lambda*sqrt(ht[, j-1])) ^ 2 + beta1 * ht[, j-1],
ht[, j ] <- omega + alpha1 * (eB -lambda*sqrt(hB))^ 2 + beta1 * hB
)
et[, j]  <- zt[, j] * sqrt(ht[, j])
}
Ft<-Fut*exp(-0.5*rowSums(ht)+rowSums(et))
payoff<-pmax(iopt * (Ft - Strike),0)
OW\$G[i] = exp(-Wibor *ttm) * sum(payoff) / N

}
)
``````
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