a two-sided linear formula object describing both the
fixed-effects and random-effects part of the model, with the
response on the left of a ~ operator and the terms, separated
by + operators, on the right. Random-effects terms are
distinguished by vertical bars (|) separating expressions
for design matrices from grouping factors. Two vertical bars
(||) can be used to specify multiple uncorrelated random
effects for the same grouping variable. (Because of the way it is
implemented, the ||-syntax works
only for design matrices containing
numeric (continuous) predictors; to fit models with independent
categorical effects, see dummy or the lmer_alt
function from the afex package.)
data
an optional data frame containing the variables named in
formula. By default the variables are taken from the
environment from which lmer is called. While data is
optional, the package authors strongly recommend its use,
especially when later applying methods such as update and
drop1 to the fitted model (such methods are not
guaranteed to work properly if data is omitted). If
data is omitted, variables will be taken from the environment
of formula (if specified as a formula) or from the parent
frame (if specified as a character vector).
REML
logical scalar - Should the estimates be chosen to
optimize the REML criterion (as opposed to the log-likelihood)?
control
a list (of correct class, resulting from
lmerControl() or glmerControl()
respectively) containing control parameters, including the nonlinear
optimizer to be used and parameters to be passed through to the
nonlinear optimizer, see the *lmerControl documentation for
details.
start
a named list of starting values for the
parameters in the model. For lmer this can be a numeric
vector or a list with one component named "theta".
verbose
integer scalar. If > 0 verbose output is
generated during the optimization of the parameter estimates. If
> 1 verbose output is generated during the individual PIRLS
steps.
subset
an optional expression indicating the subset of the rows
of data that should be used in the fit. This can be a logical
vector, or a numeric vector indicating which observation numbers are
to be included, or a character vector of the row names to be
included. All observations are included by default.
weights
an optional vector of ‘prior weights’ to be used
in the fitting process. Should be NULL or a numeric vector.
Prior weights are not normalized or standardized in
any way. In particular, the diagonal of the residual covariance
matrix is the squared residual standard deviation parameter
sigma times the vector of inverse weights.
Therefore, if the weights have relatively large magnitudes,
then in order to compensate, the sigma parameter will
also need to have a relatively large magnitude.
na.action
a function that indicates what should happen when the
data contain NAs. The default action (na.omit,
inherited from the 'factory fresh' value of
getOption("na.action")) strips any observations with any
missing values in any variables.
offset
this can be used to specify an a priori known
component to be included in the linear predictor during
fitting. This should be NULL or a numeric vector of length
equal to the number of cases. One or more offset
terms can be included in the formula instead or as well, and if more
than one is specified their sum is used. See
model.offset.
contrasts
an optional list. See the contrasts.arg of
model.matrix.default.
devFunOnly
logical - return only the deviance evaluation
function. Note that because the deviance function operates on
variables stored in its environment, it may not return
exactly the same values on subsequent calls (but the results
should always be within machine tolerance).
...
other potential arguments. A method argument was
used in earlier versions of the package. Its functionality has been
replaced by the REML argument.
Details
If the formula argument is specified as a character
vector, the function will attempt to coerce it to a formula.
However, this is not recommended (users who want to construct
formulas by pasting together components are advised to use
as.formula or reformulate); model fits
will work but subsequent methods such as drop1,
update may fail.
When handling perfectly collinear predictor variables
(i.e. design matrices of less than full rank),
[gn]lmer is not quite as sophisticated
as some simpler modeling frameworks such as
lm and glm. While it does
automatically drop collinear variables (with a message
rather than a warning), it does not automatically fill
in NA values for the dropped coefficients;
these can be added via
fixef(fitted.model,add.dropped=TRUE).
This information can also be retrieved via
attr(getME(fitted.model,"X"),"col.dropped").
the deviance function returned when devFunOnly is
TRUE takes a single numeric vector argument, representing
the theta vector. This vector defines the scaled
variance-covariance matrices of the random effects, in the
Cholesky parameterization. For models with only simple
(intercept-only) random effects, theta is a vector of the
standard deviations of the random effects. For more complex or
multiple random effects, running getME(.,"theta") to
retrieve the theta vector for a fitted model and examining
the names of the vector is probably the easiest way to determine
the correspondence between the elements of the theta vector
and elements of the lower triangles of the Cholesky factors of the
random effects.
Value
An object of class merMod (more specifically,
an object of subclasslmerMod), for which many methods
are available (e.g. methods(class="merMod"))
See Also
lm for linear models;
glmer for generalized linear; and
nlmer for nonlinear mixed models.
Examples
## linear mixed models - reference values from older code
(fm1 <- lmer(Reaction ~ Days + (Days | Subject), sleepstudy))
summary(fm1)# (with its own print method; see class?merMod % ./merMod-class.Rd
str(terms(fm1))
stopifnot(identical(terms(fm1, fixed.only=FALSE),
terms(model.frame(fm1))))
attr(terms(fm1, FALSE), "dataClasses") # fixed.only=FALSE needed for dataCl.
fm1_ML <- update(fm1,REML=FALSE)
(fm2 <- lmer(Reaction ~ Days + (Days || Subject), sleepstudy))
anova(fm1, fm2)
sm2 <- summary(fm2)
print(fm2, digits=7, ranef.comp="Var") # the print.merMod() method
print(sm2, digits=3, corr=FALSE) # the print.summary.merMod() method
(vv <- vcov.merMod(fm2, corr=TRUE))
as(vv, "corMatrix")# extracts the ("hidden") 'correlation' entry in @factors
## Fit sex-specific variances by constructing numeric dummy variables
## for sex and sex:age; in this case the estimated variance differences
## between groups in both intercept and slope are zero ...
data(Orthodont,package="nlme")
Orthodont$nsex <- as.numeric(Orthodont$Sex=="Male")
Orthodont$nsexage <- with(Orthodont, nsex*age)
lmer(distance ~ age + (age|Subject) + (0+nsex|Subject) +
(0 + nsexage|Subject), data=Orthodont)