You are slightly over-concerned with the warning message:

fixed-effect model matrix is rank deficient so dropping 7 columns / coefficients.

It is a warning not an error. There is neither misuse of `lmer`

nor ill-specification of model formula, thus you will obtain an estimated model. But to answer your question, I shall strive to explain it.

During execution of `lmer`

, your model formula is broken into a **fixed effect formula** and a **random effect formula**, and for each a **model matrix** is constructed. Construction for the fixed one is via the standard model matrix constructor `model.matrix`

; construction for the random one is complicated but not related to your question, so I just skip it.

For your model, you can check what the fixed effect model matrix looks like by:

```
fix.formula <- F2_difference ~ sex + nasal + type + vowelLabel +
type * vowelLabel + nasal * type
X <- model.matrix (fix.formula, data.df)
```

All your variables are factor so `X`

will be binary. Though `model.matrix`

applies `contrasts`

for each factor and their interaction, it is still possible that `X`

does not end up with full column rank, as a column may be a linear combination of some others (*which can either be precise or numerically close*). In your case, some levels of one factor may be nested in some levels of another.

Rank deficiency can arise in many different ways. The other answer shares a CrossValidated answer offering substantial discussions, on which I will make some comments.

- For case 1, people can actually do a feature selection model via say, LASSO.
- Cases 2 and 3 are related to the data collection process. A good design of experiment is the best way to prevent rank-deficiency, but for many people who build models, the data are already there and no improvement (like getting more data) is possible. However, I would like to stress that even for a dataset without rank-deficiency, we can still get this problem if we don't use it carefully. For example, cross-validation is a good method for model comparison. To do this we need to split the complete dataset into a training one and a test one, but without care we may get a rank-deficient model from the training dataset.
- Case 4 is a big problem that could be completely out of our control. Perhaps a natural choice is to reduce model complexity, but an alternative is to try penalized regression.
- Case 5 is a numerical concern leading to numerical rank-deficiency and this is a good example.
- Cases 6 and 7 tell the fact that numerical computations are performed in finite precision. Usually these won't be an issue if case 5 is dealt with properly.

So, sometimes we can workaround the deficiency but it is not always possible to achieve this. Thus, any well-written model fitting routine, like `lm`

, `glm`

, `mgcv::gam`

, will apply QR decomposition for `X`

to only use its full-rank subspace, i.e., a maximum subset of `X`

's columns that gives a full-rank space, for estimation, fixing coefficients associated with the rest of the columns at 0 or `NA`

. The warning you got just implies this. There are originally `ncol(X)`

coefficients to estimate, but due to deficiency, only `ncol(X) - 7`

will be estimated, with the rest being 0 or `NA`

. Such numerical workaround ensures that a least squares solution can be obtained in the most stable manner.

To better digest this issue, you can use `lm`

to fit a linear model with `fix.formula`

.

```
fix.fit <- lm(fix.formula, data.df, method = "qr", singular.ok = TRUE)
```

`method = "qr"`

and `singular.ok = TRUE`

are default, so actually we don't need to set it. But if we specify `singular.ok = FALSE`

, `lm`

will stop and complain about rank-deficiency.

```
lm(fix.formula, data.df, method = "qr", singular.ok = FALSE)
#Error in lm.fit(x, y, offset = offset, singular.ok = singular.ok, ...) :
# singular fit encountered
```

You can then check the returned values in `fix.fit`

.

```
p <- length(coef)
coef <- fix.fit$coef
no.NA <- sum(is.na(coef))
rank <- fix.fit$rank
```

It is guaranteed that `p = ncol(X)`

, but you should see `no.NA = 7`

and `rank + no.NA = p`

.

Exactly the same thing happens inside `lmer`

. `lm`

will not report deficiency while `lmer`

does. This is in fact informative, as too often, I see people asking why `lm`

returns `NA`

for some coefficients.

**Update 1 (2016-05-07):**

Let me see if I have this right: The short version is that one of my predictor variables is correlated with another, but I shouldn't worry about it. It is appropriate to use factors, correct? And I can still compare models with `anova`

or by looking at the BIC?

Don't worry about the use of `summary`

or `anova`

. Methods are written so that the correct number of parameters (degree of freedom) will be used to produce valid summary statistics.

**Update 2 (2016-11-06):**

Let's also hear what package author of `lme4`

would say: rank deficiency warning mixed model lmer. Ben Bolker has mentioned `caret::findLinearCombos`

, too, particularly because the OP there want to address deficiency issue himself.

**Update 3 (2018-07-27):**

Rank-deficiency is not a problem for valid model estimation and comparison, but could be a hazard in prediction. I recently composed a detailed answer with simulated examples on CrossValidated: R `lm`

, Could anyone give me an example of the misleading case on “prediction from a rank-deficient”? So, yes, **in theory** we should avoid rank-deficient estimation. But **in reality, there is no so-called "true model"**: we try to learn it from data. We can never compare an estimated model to "truth"; the best bet is to choose the best one from a number of models we've built. So if the "best" model ends up rank-deficient, we can be skeptical about it but probably there is nothing we can do immediately.