I'm trying to understand the function lmer. I've found plenty of information about how to use the command, but not much about what it's actually doing (save for some cryptic comments here: http://www.bioconductor.org/help/course-materials/2008/PHSIntro/lme4Intro-handout-6.pdf). I'm playing with the following simple example:

```
library(data.table)
library(lme4)
options(digits=15)
n<-1000
m<-100
data<-data.table(id=sample(1:m,n,replace=T),key="id")
b<-rnorm(m)
data$y<-rand[data$id]+rnorm(n)*0.1
fitted<-lmer(b~(1|id),data=data,verbose=T)
fitted
```

I understand that lmer is fitting a model of the form Y_{ij} = beta + B_i + epsilon_{ij}, where epsilon_{ij} and B_i are independent normals with variances sigma^2 and tau^2 respectively. If theta = tau/sigma is fixed, I computed the estimate for beta with the correct mean and minimum variance to be

```
c = sum_{i,j} alpha_i y_{ij}
```

where

```
alpha_i = lambda/(1 + theta^2 n_i)
lambda = 1/[\sum_i n_i/(1+theta^2 n_i)]
n_i = number of observations from group i
```

~~I also computed the following unbiased estimate for sigma^2:~~

~~s^2 = \sum_{i,j} alpha_i (y_{ij} - c)^2 / (1 + theta^2 - lambda)~~

These estimates seem to agree with what lmer produces. However, I can't figure out how log likelihood is defined in this context. I calculated the probability density to be

```
pd(Y_{ij}=y_{ij}) = \prod_{i,j}[f_sigma(y_{ij}-ybar_i)]
* prod_i[f_{sqrt(sigma^2/n_i+tau^2)}(ybar_i-beta) sigma sqrt(2 pi/n_i)]
```

where

```
ybar_i = \sum_j y_{ij}/n_i (the mean of observations in group i)
f_sigma(x) = 1/(sqrt{2 pi}sigma) exp(-x^2/(2 sigma)) (normal density with sd sigma)
```

But log of the above is not what lmer produces. How is log likelihood computed in this case (and for bonus marks, why)?

**Edit:** Changed notation for consistency, striked out incorrect formula for standard deviation estimate.

whatand thewhyyou might take a peek at Doug Bates' draft book on lme4 ... lme4.r-forge.r-project.org/lMMwR/lrgprt.pdf (specifically section 1.4). Not sure how up-to-date the code in the book is, with regards to the last big update of lme4 -- but it's essential reading. – Nate Pope Jan 7 '14 at 22:06noteasy). Any book on mixed models (e.g. Pinheiro and Bates 2000) would be a good start. – Ben Bolker Jan 8 '14 at 3:14