I am struggling to understand how, in R, to generate predictive simulations for new data using a multilevel linear regression model with a single set of random intercepts. Following the example on pp. 146-147 of this text, I can execute this task for a simple linear model with no random effects. What I can't wrap my head around is how to extend the set-up to accommodate random intercepts for a factor added to that model.

I'll use `iris`

and some fake data to show where I'm getting stuck. I'll start with a simple linear model:

```
mod0 <- lm(Sepal.Length ~ Sepal.Width, data = iris)
```

Now let's use that model to generate 1,000 predictive simulations for 250 new cases. I'll start by making up those cases:

```
set.seed(20912)
fakeiris <- data.frame(Sepal.Length = rnorm(250, mean(iris$Sepal.Length), sd(iris$Sepal.Length)),
Sepal.Width = rnorm(250, mean(iris$Sepal.Length), sd(iris$Sepal.Length)),
Species = sample(as.character(unique(iris$Species)), 250, replace = TRUE),
stringsAsFactors=FALSE)
```

Following the example in the aforementioned text, here's what I do to get 1,000 predictive simulations for each of those 250 new cases:

```
library(arm)
n.sims = 1000 # set number of simulations
n.tilde = nrow(fakeiris) # set number of cases to simulate
X.tilde <- cbind(rep(1, n.tilde), fakeiris[,"Sepal.Width"]) # create matrix of predictors describing those cases; need column of 1s to multiply by intercept
sim.fakeiris <- sim(mod0, n.sims) # draw the simulated coefficients
y.tilde <- array(NA, c(n.sims, n.tilde)) # build an array to hold results
for (s in 1:n.sims) { y.tilde[s,] <- rnorm(n.tilde, X.tilde %*% sim.fakeiris@coef[s,], sim.fakeiris@sigma[s]) } # use matrix multiplication to fill that array
```

That works fine, and now we can do things like `colMeans(y.tilde)`

to inspect the central tendencies of those simulations, and `cor(colMeans(y.tilde), fakeiris$Sepal.Length)`

to compare them to the (fake) observed values of Sepal.Length.

Now let's try an extension of that simple model in which we assume that the intercept varies across groups of observations --- here, species. I'll use `lmer()`

from the `lme4`

package to estimate a simple multilevel/hierarchical model that matches that description:

```
library(lme4)
mod1 <- lmer(Sepal.Length ~ Sepal.Width + (1 | Species), data = iris)
```

Okay, that works, but now what? I run:

```
sim.fakeiris.lmer <- sim(mod1, n.sims)
```

When I use `str()`

to inspect the result, I see that it is an object of class sim.merMod with three components:

`@fixedef`

, a 1,000 x 2 matrix with simulated coefficients for the fixed effects (the intercept and Sepal.Width)`@ranef`

, a 1,000 x 3 matrix with simulated coefficients for the random effects (the three species)`@sigma`

, a vector of length 1,000 containing the sigmas associated with each of those simulations

I can't wrap my head around how to extend the matrix construction and multiplication used for the simple linear model to this situation, which adds another dimension. I looked in the text, but I could only find an example (pp. 272-275) for a single case in a single group (here, species). The real-world task I'm aiming to perform involves running simulations like these for 256 new cases (pro football games) evenly distributed across 32 groups (home teams). I'd greatly appreciate any assistance you can offer.

**Addendum**. Stupidly, I hadn't looked at the details on `simulate.merMod()`

in `lme4`

before posting this. I have now. It seems like it should do the trick, but when I run `simulate(mod0, nsim = 1000, newdata = fakeiris)`

, the result has only 150 rows. The values look sensible, but there are 250 rows (cases) in `fakeiris`

. Where is that 150 coming from?