Table of Contents:

- A simple example for walkthrough
- Suggestion for users
- Helpful information that we can get from the fitted model object
- OK, I see what the problem is now, but how to make
`predict`

work?
- Is there a better way to avoid such problem at all?

**A simple example for walkthrough**

Here is simple enough reproducible example to hint you what has happened.

```
train <- data.frame(y = runif(4), x = c(runif(3), NA), f = factor(letters[1:4]))
test <- data.frame(y = runif(4), x = runif(4), f = factor(letters[1:4]))
fit <- lm(y ~ x + f, data = train)
predict(fit, newdata = test)
#Error in model.frame.default(Terms, newdata, na.action = na.action, xlev = object$xlevels) :
# factor f has new levels d
```

I am fitting a model with more parameters than data so the model is rank-deficient (to be explained in the end). However, this does not affect how `lm`

and `predict`

work.

If you just check `table(train$f)`

and `table(test$f)`

it is not useful as the problem is not caused by variable `f`

but by `NA`

in `x`

. `lm`

and `glm`

drop incomplete cases, i.e., rows with at least one `NA`

(see ?`complete.cases`

) for model fitting. They have to do so as otherwise the underlying FORTRAN routine for QR factorization would fail because it can not handle `NA`

. If you check the documentation at `?lm`

you will see this function has an argument `na.action`

which defaults to `na.omit`

. You can also set it to `na.exclude`

but `na.pass`

which retains `NA`

will cause FORTRAN error:

```
fit <- lm(y ~ x + f, data = train, na.action = na.pass)
#Error in lm.fit(x, y, offset = offset, singular.ok = singular.ok, ...) :
# NA/NaN/Inf in 'x'
```

Let's remove `NA`

from the training dataset.

```
train <- na.omit(train)
train$f
#[1] a b c
#Levels: a b c d
```

`f`

now has an unused level `"d"`

. `lm`

and `glm`

will drop unused levels when building the model frame (and later the model matrix):

```
## source code of lm; don't run
mf$drop.unused.levels <- TRUE
mf[[1L]] <- quote(stats::model.frame)
mf <- eval(mf, parent.frame())
```

This is not user controllable. The reason is that if an unused level is included, it will generate a column of zeros in the model matrix.

```
mf <- model.frame(y ~ x + f, data = train, drop.unused.levels = FALSE)
model.matrix(y ~ x + f, data = mf)
# (Intercept) x fb fc fd
#1 1 0.90021178 0 0 0
#2 1 0.10188534 1 0 0
#3 1 0.05881954 0 1 0
#attr(,"assign")
#[1] 0 1 2 2 2
#attr(,"contrasts")
#attr(,"contrasts")$f
#[1] "contr.treatment"
```

This is undesired as it produces `NA`

coefficient for dummy variable `fd`

. By `drop.unused.levels = TRUE`

as forced by `lm`

and `glm`

:

```
mf <- model.frame(y ~ x + f, data = train, drop.unused.levels = TRUE)
model.matrix(y ~ x + f, data = mf)
# (Intercept) x fb fc
#1 1 0.90021178 0 0
#2 1 0.10188534 1 0
#3 1 0.05881954 0 1
#attr(,"assign")
#[1] 0 1 2 2
#attr(,"contrasts")
#attr(,"contrasts")$f
#[1] "contr.treatment"
```

The `fd`

is gone, and

```
mf$f
#[1] a b c
#Levels: a b c
```

The now non-existing `"d"`

level will cause the "new factor level" error in `predict`

.

**Suggestion for users**

It is highly recommended that all users do the following manually when fitting models:

**[No. 1]** remove incomplete cases;
**[No. 2]** drop unused factor levels.

This is exactly the procedure as recommended here: How to debug "contrasts can be applied only to factors with 2 or more levels" error? This gets users aware of what `lm`

and `glm`

do under the hood, and makes their debugging life much easier.

Note, there should be another recommendation in the list:

**[No. 0]** do subsetting yourself

Users may occasionally use `subset`

argument. But there is a potential pitfall: not all factor levels might appear in the subsetted dataset, thus you may get "new factor levels" when using `predict`

later.

The above advice is particularly important when you write functions wrapping `lm`

or `glm`

. You want your functions to be robust. Ask your function to return an informative error rather than waiting for `lm`

and `glm`

to complain.

**Helpful information that we can get from the fitted model object**

`lm`

and `glm`

return an `xlevels`

value in the fitted object. It contains the factor levels **actually** used for model fitting.

```
fit$xlevels
#$f
#[1] "a" "b" "c"
```

So in case you have not followed the recommendations listed above and have got into trouble with factor levels, this `xlevels`

should be the first thing to inspect.

If you want to use something like `table`

to count how many cases there are for each factor levels, here is a way: Get number of data in each factor level (as well as interaction) from a fitted lm or glm [R], although making a model matrix can use much RAM.

**OK, I see what the problem is now, but how to make **`predict`

work?

If you can not choose to work with a different set of `train`

and `test`

dataset (see the next section), you need to set those factor levels in the `test`

but not in `xlevels`

to `NA`

. Then `predict`

will just predict `NA`

for such incomplete cases.

**Is there a better way to avoid such problem at all?**

People split data into `train`

and `test`

as they want to do cross-validation. The first step is to apply `na.omit`

on your full dataset to get rid of `NA`

noise. Then we could do a random partitioning on what is left, but this this naive way may end up with

- some factor levels in
`test`

but not in `train`

*(oops, we get "new factor level" error when using *`predict`

);
- some factor variables in
`train`

only have 1 level after unused levels removed *(oops, we get "contrasts" error when using *`lm`

and `glm`

);

So, it is highly recommended that you do some more sophisticated partitioning like stratified sampling.

There is in fact another hazard, but not causing programming errors:

- the model matrix for
`train`

is rank-deficient *(oops, we get a "prediction for rank-deficient model may be misleading" warning when using *`predict`

).

Regarding the rank-deficiency in model fitting, see lme4::lmer reports "fixed-effect model matrix is rank deficient", do I need a fix and how to? Rank-deficiency does not cause problem for model estimation and checking, but can be a hazard for prediction: R `lm`

, Could anyone give me an example of the misleading case on “prediction from a rank-deficient”? However, such issue is more difficult to avoid, particularly if you have many factors and possibly with interaction.

`table(train$Product_Category_1)`

and`table(test$Product_Category_1)`

tell you? There is not much we can do to help without a reproducible example here. – Roland Jul 27 '18 at 6:53`table(train$Product_Category_1)`

and`table(test$Product_Category_1)`

show they have the same factors (edited the post) – ZhouW Jul 27 '18 at 7:03`NA`

values in other variables.`lm`

applies`na.omit`

and thereby could remove all observations of a specific factor level. – Roland Jul 27 '18 at 8:48