I am trying to do the matrix multiplication `S_g`

for each i, and each g with i. This is what I have tried so far, but it takes a huge amount of time to complete. Is there a more computationally efficient method to do exactly the same thing?

The main thing to note from this formula is the `S_g`

uses X_gamma and Y[,i] in matrix multiplication set-up. X_gamma is dependent on value `g`

. Therefore, for each i, I have to perform `g`

matrix multiplications.

Here is the logic:

- For each i, the computation needs to be done for each g. Then, for each g, X_gamma is selected as a subset of X. Here is how X_gamma is determined. Let's take g = 3. When we look at 'set[3,]', we have that column B is the only one with value != 0. Therefore, I select the column B in X, and that would be X_gamma.

My main problem is that IN REALITY, ** g = 13,000**, and

**.**

`i = 700`

```
library(foreach)
library(doParallel) ## parallel backend for the foreach function
registerDoParallel()
T = 3
c = 100
X <- zoo(data.frame(A = c(0.1, 0.2, 0.3), B = c(0.4, 0.5, 0.6), C = c(0.7,0.8,0.9)),
order.by = seq(from = as.Date("2013-01-01"), length.out = 3, by = "month"))
Y <- zoo(data.frame(Stock1 = rnorm(3,0,0.5), Stock2 = rnorm(3,0,0.5), Stock3 = rnorm(3,0,0.5)),
order.by = seq(from = as.Date("2013-01-01"), length.out = 3, by = "month"))
l <- rep(list(0:1),ncol(X))
set = do.call(expand.grid, l)
colnames(set) <- colnames(X)
I = diag(T)
denom <- foreach(i=1:ncol(Y)) %dopar% {
library(zoo)
library(stats)
library(Matrix)
library(base)
result = c()
for(g in 1:nrow(set)) {
X_gamma = X[,which(colnames(X) %in% colnames(set[which(set[g,] != 0)]))]
S_g = Y[,i] %*% (I - (c/(1+c))*(X_gamma %*% solve(crossprod(X_gamma)) %*% t(X_gamma))) %*% Y[,i]
result[g] = ((1+c)^(-sum(set[g,])/2)) * ((S_g)^(-T/2))
}
sum(result)
}
```

Thank you for your help!

`data.table`

. – Metrics Sep 10 '13 at 17:47