I'm having trouble optimizing a multivariate normal log-likelihood in R. If anyone has a good solution for that, please let me know. Specifically, I cannot seem to keep the variance-covariance matrix positive-definite and the parameters in a reasonable range.

Let me introduce the problem more completely. I am essentially trying to simultaneously solve these two regression equations using MLE:

$$ y_1 = \beta_1 + \beta_2 x_1 + \beta_3 x_2 \\ y_2 = \beta_4 + \beta_3 x_1 + \beta_5 x_2 $$

The fact that $\beta_3$ is in both equations is not a mistake. I try to solve this using MLE by maximizing the likelihood of the multivariate normal distribution for $Y = (y_1, y_2)^\top$ where the mean is parameterized as above in the regression equations.

I've attached the log-likelihood function as I believe it should be, where I constrain the variance covariance matrix to be positive-definite by recreating it from necessarily positive eigenvalues and a cholesky decomposition.

```
mvrestricted_ll <- function(par, Y, X) {
# Indices
n <- nrow(X)
nbetas <- (2 + 3 * (ncol(Y) - 1))
# Extract parameters
beta <- par[1:nbetas]
eigvals <- exp(par[(nbetas + 1):(nbetas + ncol(Y))]) # constrain to be positive
chole <- par[(nbetas + ncol(Y) + 1):(nbetas + ncol(Y) + ncol(Y)*(ncol(Y)+1)/2)]
# Build Sigma from positive eigenvalues and cholesky (should be pos def)
L <- diag(ncol(Y))
L[lower.tri(L, diag=T)] <- chole
Sigma <- diag(eigvals) + tcrossprod(L)
# Linear predictor
# Hard coded for 2x2 example for now
mu <- cbind(beta[1] + beta[2]*X[,1] + beta[3]*X[,2],
beta[4] + beta[3]*X[,1] + beta[5]*X[,2])
yminmu <- Y - mu
nlogs <- n * log(det(Sigma))
invSigma <- solve(Sigma)
meat <- yminmu %*% tcrossprod(invSigma, yminmu)
return(- nlogs - sum(diag(meat)))
}
# Create fake data
n <- 1000
p <- 2
set.seed(20160201)
X <- matrix(rnorm(n*p), nrow = n)
set.seed(20160201)
Y <- matrix(rnorm(n*p), nrow = n)
# Initialize parameters
initpars <- c(rep(0, (2 + 3 * (ncol(Y) - 1)) + ncol(Y) + ncol(Y)*(ncol(Y)+1)/2))
# Optimize fails with BFGS
optim(par = initpars, fn = mvrestricted_ll, X=X, Y=Y, method = "BFGS")
# Optim does not converge with Nelder-mead, if you up the maxits it also fails
optim(par = initpars, fn = mvrestricted_ll, X=X, Y=Y)
```

Any help would be greatly appreciated.

EDIT: I should note that just letting Sigma be a vector in the parameters and then returning a very large value whenever it is not positive definite does not work either.