I am trying to estimate a simple AR(1) model in R of the form **y[t] = alpha + beta * y[t-1] + u[t] ** with u[t] being normally distributed with mean zero and standard deviation sigma.

I have simulated an AR(1) model with **alpha = 10** and **beta = 0.1**:

```
library(stats)
data<-arima.sim(n=1000,list(ar=0.1),mean=10)
```

First check: OLS yields the following results:

```
lm(data~c(NA,data[1:length(data)-1]))
Call:
lm(formula = data ~ c(NA, data[1:length(data) - 1]))
Coefficients:
(Intercept) c(NA, data[1:length(data) - 1])
10.02253 0.09669
```

But my goal is to estimate the coefficients with ML. My negative log-likelihood function is:

```
logl<-function(sigma,alpha,beta){
-sum(log((1/(sqrt(2*pi)*sigma)) * exp(-((data-alpha-beta*c(NA,data[1:length(data)-1]))^2)/(2*sigma^2))))
}
```

that is, the sum of all log-single observation normal distributions, that are transformed by u[t] = y[t] - alpha - beta*y[t-1]. The lag has been created (just like in the OLS estimation above) by c(NA,data[1:length(data)-1]).

When I try to put it at work I get the following error:

```
library(stats4)
mle(logl,start=list(sigma=1,alpha=5,beta=0.05),method="L-BFGS-B")
Error in optim(start, f, method = method, hessian = TRUE, ...) :
L-BFGS-B needs finite values of 'fn'
```

My log-likelihood function must be correct, when I try to estimate a linear model of the form **y[t] = alpha + beta * x[t] + u[t]** it works perfectly.

I just do not see how my initial values lead to a non-finite result? Trying any other initial values does not solve the problem.

Any help is highly appreciated!

`library`

calls that would identify and load the function. (I also don't see recognition in your code of the fact that lagged variables have NA's.) – 42- Sep 8 '13 at 16:03`stats4::mle`

, so`library(stats4)`

should do it. At least this is a base package ... – Ben Bolker Sep 8 '13 at 17:26`grid`

and not routinely loaded despite being recommended. – 42- Sep 8 '13 at 18:00`library(stats4)`

. I haven't looked carefully, but I strongly suspect that the primary issue is the`NA`

values in the lagged variables -- this would make the ML`NA`

. Rule #1: always check by evaluating your log-likelihood function at any proposed initial values to make sure the results make sense! – Ben Bolker Sep 8 '13 at 18:27