# Adding lagged variables to an lm model?

I'm using lm on a time series, which works quite well actually, and it's super super fast.

Let's say my model is:

``````> formula <- y ~ x
``````

I train this on a training set:

``````> train <- data.frame( x = seq(1,3), y = c(2,1,4) )
> model <- lm( formula, train )
``````

... and I can make predictions for new data:

``````> test <- data.frame( x = seq(4,6) )
> test\$y <- predict( model, newdata = test )
> test
x        y
1 4 4.333333
2 5 5.333333
3 6 6.333333
``````

This works super nicely, and it's really speedy.

I want to add lagged variables to the model. Now, I could do this by augmenting my original training set:

``````> train\$y_1 <- c(0,train\$y[1:nrow(train)-1])
> train
x y y_1
1 1 2   0
2 2 1   2
3 3 4   1
``````

update the formula:

``````formula <- y ~ x * y_1
``````

... and training will work just fine:

``````> model <- lm( formula, train )
> # no errors here
``````

However, the problem is that there is no way of using 'predict', because there is no way of populating y_1 in a test set in a batch manner.

Now, for lots of other regression things, there are very convenient ways to express them in the formula, such as `poly(x,2)` and so on, and these work directly using the unmodified training and test data.

So, I'm wondering if there is some way of expressing lagged variables in the formula, so that `predict` can be used? Ideally:

``````formula <- y ~ x * lag(y,-1)
model <- lm( formula, train )
test\$y <- predict( model, newdata = test )
``````

... without having to augment (not sure if that's the right word) the training and test datasets, and just being able to use `predict` directly?

• This is something that I think that R should be able to handle much more elegantly. – Charlie Oct 31 '12 at 0:11
• @Charlie, the question is tagged 'r'. What language do you think the code above is written in? – Hugh Perkins Oct 31 '12 at 4:20
• I know that it's written in R. I was just commenting that I don't think that R handles time series operations that well (even with the `dyn` package) and that I wish there was a package that could do it more elegantly. As an example, I think that Stata makes time series operations very easy. The `dyn` package helps with regression, but adding lagged variables to a data frame, for example, requires a bit of a hack `df\$lagged <- c(NA, head(df\$var, -1))`. – Charlie Oct 31 '12 at 14:58
• Ah I see: "should" as in "I wish it did", rather than "should" as in "I think it does". – Hugh Perkins Oct 31 '12 at 16:08
• I think the last block of your code works, if `test` contain column `y` before you overwrite it. – user3226167 Mar 23 '17 at 9:05

Have a look at e.g. the dynlm package which gives you lag operators. More generally the Task Views on Econometrics and Time Series will have lots more for you to look at.

Here is the beginning of its examples -- a one and twelve month lag:

``````R>      data("UKDriverDeaths", package = "datasets")
R>      uk <- log10(UKDriverDeaths)
R>      dfm <- dynlm(uk ~ L(uk, 1) + L(uk, 12))
R>      dfm

Time series regression with "ts" data:
Start = 1970(1), End = 1984(12)

Call:
dynlm(formula = uk ~ L(uk, 1) + L(uk, 12))

Coefficients:
(Intercept)     L(uk, 1)    L(uk, 12)
0.183        0.431        0.511

R>
``````
• Oh, that looks super cool! Downloading and trying that now. – Hugh Perkins Oct 27 '12 at 2:58
• If you have a moment, how do I handle test data? ie, if I train on `train <- data.frame( y = head(UKDriverDeaths,96) )`, and then I set my test data as `test <- data.frame( y = rep(UKDriverDeaths[97],96) )`, I get a straight horizontal line, ie it's using the lagged values of y from my test data set, rather than using the calculated values. (Edit: no better using NAs, ie `test <- data.frame( y = c( UKDriverDeaths[97], rep(NA, 95) ) )`: it just gives `NA` for everything ) (Edit2: oh, maybe using `update`?) – Hugh Perkins Oct 27 '12 at 4:10
• Can't seem to figure out how to get it to predict. `update(model,end=192)` doesn't seeem to work, neither does `model <- dynlm( y ~ L(y,1), end= 192)`. – Hugh Perkins Oct 27 '12 at 5:59
• Updated the question with my attempts using the `dyn` library, which is related to `dynlm` library, at least semantically. – Hugh Perkins Oct 27 '12 at 7:44

Following Dirk's suggestion on `dynlm`, I couldn't quite figure out how to predict, but searching for that led me to `dyn` package via https://stats.stackexchange.com/questions/6758/1-step-ahead-predictions-with-dynlm-r-package

Then after several hours of experimentation I came up with the following function to handle the prediction. There were quite a few 'gotcha's on the way, eg you can't seem to `rbind` time series, and the result of predict is offset by `start` and a whole bunch of things like that, so I feel this answer adds significantly compared to just naming a package, though I have upvoted Dirk's answer.

So, a solution that works is:

• use the `dyn` package
• use the following method for prediction

predictDyn method:

``````# pass in training data, test data,
# it will step through one by one
# need to give dependent var name, so that it can make this into a timeseries
predictDyn <- function( model, train, test, dependentvarname ) {
Ntrain <- nrow(train)
Ntest <- nrow(test)
# can't rbind ts's apparently, so convert to numeric first
train[,dependentvarname] <- as.numeric(train[,dependentvarname])
test[,dependentvarname] <- as.numeric(test[,dependentvarname])
testtraindata <- rbind( train, test )
testtraindata[,dependentvarname] <- ts( as.numeric( testtraindata[,dependentvarname] ) )
for( i in 1:Ntest ) {
result <- predict(model,newdata=testtraindata,subset=1:(Ntrain+i-1))
testtraindata[Ntrain+i,dependentvarname] <- result[Ntrain + i + 1 - start(result)][1]
}
return( testtraindata[(Ntrain+1):(Ntrain + Ntest),] )
}
``````

Example usage:

``````library("dyn")

# size of training and test data
N <- 6
predictN <- 10

# create training data, which we can get exact fit on, so we can check the results easily
traindata <- c(1,2)
for( i in 3:N ) { traindata[i] <- 0.5 + 1.3 * traindata[i-2] + 1.7 * traindata[i-1] }
train <- data.frame( y = ts( traindata ), foo = 1)

# create testing data, bunch of NAs
test <- data.frame( y = ts( rep(NA,predictN) ), foo = 1)

# fit a model
model <- dyn\$lm( y ~ lag(y,-1) + lag(y,-2), train )
# look at the model, it's a perfect fit. Nice!
print(model)

test <- predictDyn( model, train, test, "y" )
print(test)

# nice plot
plot(test\$y, type='l')
``````

Output:

``````> model

Call:
lm(formula = dyn(y ~ lag(y, -1) + lag(y, -2)), data = train)

Coefficients:
(Intercept)   lag(y, -1)   lag(y, -2)
0.5          1.7          1.3

> test
y foo
7     143.2054   1
8     325.6810   1
9     740.3247   1
10   1682.4373   1
11   3823.0656   1
12   8686.8801   1
13  19738.1816   1
14  44848.3528   1
15 101902.3358   1
16 231537.3296   1
``````

Edit: hmmm, this is super slow though. Even if I limit the data in the `subset` to a constant few rows of the dataset, it takes about 24 milliseconds per prediction, or, for my task, `0.024*7*24*8*20*10/60/60` = `1.792 hours` :-O

Try the ARIMA function. The AR parameter is for auto-regressive, which means lagged y. xreg = allows you to add other X variables. You can get predictions with predict.ARIMA.

Here's a thought:

Why don't you create a new data frame? Fill a data frame with the regressors you need. You could have columns like L1, L2, ..., Lp for all lags of any variable you want and, then, you get to use your functions exactly like you would for a cross-section type of regression.

Because you will not have to operate on your data every time you call fitting and prediction functions, but will have transformed the data once, it will be considerably faster. I know that Eviews and Stata provide lagging operators. It is true that there is some convenience to it. But it also is inefficient if you do not need everything functions like 'lm' compute. If you have a few hundreds of thousands of iterations to perform and you just need the forecast, or the forecast and the value of information criteria like BIC or AIC, you can beat 'lm' in speed by avoiding to make computations that you will not use -- just write an OLS estimator in a function and you're good to go.