I am currently writing a script to evaluate the (restricted) log-likelihood function for use in linear mixed models. I need it to calculate the likelihood of a model with some parameters fixed to arbitrary values. Maybe this script is helpful to some of you as well!

I use `lmer()`

from `lme4`

and `logLik()`

to check whether my script works as it should. And as it seems , it does not!
As my educational background wasn't really concerned with this level of statistics, I am a bit lost finding the mistake.

Following, you will find a short example script using the sleepstudy-data:

```
# * * * * * * * * * * * * * * * * * * * * * * * *
# * example data
library(lme4)
data(sleepstudy)
dat <- sleepstudy[ (sleepstudy$Days %in% 0:4) & (sleepstudy$Subject %in% 331:333) ,]
colnames(dat) <- c("y", "x", "group")
mod0 <- lmer( y ~ 1 + x + ( 1 | group ), data = dat)
# + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + #
# #
# Evaluating the likelihood-function for a LMM #
# specified as: Y = X*beta + Z*b + e #
# #
# + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + +
# * * * * * * * * * * * * * * * * * * * * * * * *
# * the model parameters
# n is total number of individuals
# m is total number of groups, indexed by i
# p is number of fixed effects
# q is number of random effects
q <- nrow(VarCorr(mod0)$group) # number of random effects
n <- nrow(dat) # number of individuals
m <- length(unique(dat$group)) # number of goups
Y <- dat$y # response vector
X <- cbind(rep(1,n), dat$x) # model matrix of fixed effects (n x p)
beta <- as.numeric(fixef(mod0)) # fixed effects vector (p x 1)
Z.sparse <- t(mod0@Zt) # model matrix of random effect (sparse format)
Z <- as.matrix(Z.sparse) # model matrix Z (n x q*m)
b <- as.matrix(ranef(mod0)$group) # random effects vector (q*m x 1)
D <- diag(VarCorr(mod0)$group[1:q,1:q], q*m) # covariance matrix of random effects
R <- diag(1,nrow(dat))*summary(mod0)@sigma^2 # covariance matrix of residuals
V <- Z %*% D %*% t(Z) + R # (total) covariance matrix of Y
# check: values in Y can be perfectly matched using lmer's information
Y.test <- X %*% beta + Z %*% b + resid(mod0)
cbind(Y, Y.test)
# * * * * * * * * * * * * * * * * * * * * * * * *
# * the likelihood function
# profile and restricted log-likelihood (Harville, 1997)
loglik.p <- - (0.5) * ( (log(det(V))) + t((Y - X %*% beta)) %*% solve(V) %*% (Y - X %*% beta) )
loglik.r <- loglik.p - (0.5) * log(det( t(X) %*% solve(V) %*% X ))
#check: value of above function does not match the generic (restricted) log-likelihood of the mer-class object
loglik.lmer <- logLik(mod0, REML=TRUE)
cbind(loglik.p, loglik.r, loglik.lmer)
```

Maybe there are some LMM-experts here who can help? In any case your recommendations are greatly appreciated!

edit: BTW, the likelihood function for LMMs can be found in Harville (1977), (hopefully) accessible through this link: Maximum likelihood approaches to variance component estimation and to related problems

Regards, Simon

stronglyrecommend that you get the development version of`lme4`

(probably from github, via`devtools`

), which has the capability (`mkDevfunOnly=TRUE`

) of returning a deviance function – Ben Bolker Feb 13 '13 at 15:46`lme4`

and installed it using`devtools`

. Is there some further documentation on the`devFunOnly=T`

argument and the function it produces? I am particularly interested in the arguments I have to feed to the resulting deviance function, because this again is the most important step for me! – SimonG Feb 14 '13 at 12:47scaledvariance-covariance matrix (i.e. relative to the residual variance). – Ben Bolker Feb 14 '13 at 15:58