# Vectorizing a simulation

Trying to wrap my mind arround vectorizing, trying to make some simulations faster I found this very basic epidemic simulation. The code is from the book http://www.amazon.com/Introduction-Scientific-Programming-Simulation-Using/dp/1420068725/ref=sr_1_1?ie=UTF8&qid=1338069156&sr=8-1

``````#program spuRs/resources/scripts/SIRsim.r

SIRsim <- function(a, b, N, T) {
# Simulate an SIR epidemic
# a is infection rate, b is removal rate
# N initial susceptibles, 1 initial infected, simulation length T
# returns a matrix size (T+1)*3 with columns S, I, R respectively
S <- rep(0, T+1)
I <- rep(0, T+1)
R <- rep(0, T+1)
S[1] <- N
I[1] <- 1
R[1] <- 0
for (i in 1:T) {
S[i+1] <- rbinom(1, S[i], (1 - a)^I[i])
R[i+1] <- R[i] + rbinom(1, I[i], b)
I[i+1] <- N + 1 - R[i+1] - S[i+1]
}
return(matrix(c(S, I, R), ncol = 3))
}
``````

The core of the simulation is the `for` loop. My question, is since the code produces the `S[i+1]` and `R[i+1]` values from the `S[i]` and `R[i]` values, is it possible to vectorize it with an apply function?

Many thanks

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`apply` functions are mostly syntactic sugar around `for` loops, you probably wouldn't gain much speed this way. You could try the `compiler` package, or `Rcpp`. – baptiste May 26 '12 at 22:29

It's hard to 'vectorize' iterative calculations, but this is a simulation and simulations are likely to be run many times. So write this to do all the the simulations at the same time by adding an argument `M` (number of simulations to perform), allocating an M x (T + 1) matrix, and then filling in successive columns (times) of each simulation. The changes seem to be remarkably straight-forward (so I've probably made a mistake; I'm particularly concerned about the use of vectors in the second and third arguments to `rbinom`, though this is consistent with the documentation).

``````SIRsim <- function(a, b, N, T, M) {
## Simulate an SIR epidemic
## a is infection rate, b is removal rate
## N initial susceptibles, 1 initial infected, simulation length T
## M is the number of simulations to run
## returns a list of S, I, R matricies, each M simulation
## across T + 1 time points
S <- I <- R <- matrix(0, M, T + 1)
S[,1] <- N
I[,1] <- 1
for (i in seq_along(T)) {
S[,i+1] <- rbinom(M, S[,i], (1 - a)^I[,i])
R[,i+1] <- R[,i] + rbinom(M, I[,i], b)
I[,i+1] <- N + 1 - R[,i+1] - S[,i+1]
}
list(S=S, I=I, R=R)
}
``````
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