There are several ways to do this in R. Here are two examples using the "Seatbelts" time series dataset in the datasets package that comes with R.

The `arima()`

function comes in package:stats that is included with R. The function takes an argument of the form `order=c(p, d, q)`

where you you can specify the order of the auto-regressive, integrated, and the moving average component. In your question, you suggest that you want to create a AR(1) model to correct for first-order autocorrelation in the errors and that's it. We can do that with the following command:

```
arima(Seatbelts[,"drivers"], order=c(1,0,0),
xreg=Seatbelts[,c("kms", "PetrolPrice", "law")])
```

The value for order specifies that we want an AR(1) model. The xreg compontent should be a series of other Xs we want to add as part of a regression. The output looks a little bit like the output of `summary.lm()`

turned on its side.

Another alternative process might be more familiar to the way you've fit regression models is to use `gls()`

in the nlme package. The following code turns the Seatbelt time series object into a dataframe and then extracts and adds a new column (*t*) that is just a counter in the sorted time series object:

```
Seatbelts.df <- data.frame(Seatbelts)
Seatbelts.df$t <- 1:(dim(Seatbelts.df)[1])
```

The two lines above are only getting the data in shape. Since the `arima()`

function is designed for time series, it can read time series objects more easily. To fit the model with nlme you would then run:

```
library(nlme)
m <- gls(drivers ~ kms + PetrolPrice + law,
data=Seatbelts.df,
correlation=corARMA(p=1, q=0, form=~t))
summary(m)
```

The line that begins with "correlation" is the way you pass in the ARMA correlation structure to GLS. The results won't be exactly the same because `arima()`

uses maximum likelihood to estimate models and `gls()`

uses restricted maximum likelihood by default. If you add `method="ML"`

to the call to `gls()`

you will get identical estimates you got with the ARIMA function above.