**UPDATE (after comment):**

Basic `clm`

model is defined like this (see clm tutorial for details):

Generating data:

```
library(ordinal)
set.seed(1)
test.data = data.frame(y=gl(4,5),
x=matrix(c(sample(1:4,20,T)+rnorm(20), rnorm(20)), ncol=2))
head(test.data) # two independent variables
test.data$y # four levels in y
```

Constructing models:

```
fm.polr <- polr(y ~ x) # using polr
fm.clm <- clm(y ~ x) # using clm
```

Now we can access `thetas`

and `betas`

(see formula above):

```
# Thetas
fm.polr$zeta # using polr
fm.clm$alpha # using clm
# Betas
fm.polr$coefficients # using polr
fm.clm$beta # using clm
```

Obtaining linear predictors (only parts without `theta`

on the right side of the formula):

```
fm.polr$lp # using polr
apply(test.data[,2:3], 1, function(x) sum(fm.clm$beta*x)) # using clm
```

New data generation:

```
# Contains only independent variables
new.data <- data.frame(x=matrix(c(rnorm(10)+sample(1:4,10,T), rnorm(10)), ncol=2))
new.data[1,] <- c(0,0) # intentionally for demonstration purpose
new.data
```

There are four types of predictions available for `clm`

model. We are interested in `type=linear.prediction`

, which returns a list with two matrices: `eta1`

and `eta2`

. They contain linear predictors for each observation in `new.data`

:

```
lp.clm <- predict(fm.clm, new.data, type="linear.predictor")
lp.clm
```

**Note 1:** `eta1`

and `eta2`

are literally equal. Second is just a rotation of `eta1`

by 1 in `j`

index. Thus, they leave left side and right side of linear predictor scale opened respectively.

```
all.equal(lp.clm$eta1[,1:3], lp.clm$eta2[,2:4], check.attributes=FALSE)
# [1] TRUE
```

**Note 2:** Prediction for first line in `new.data`

is equal to `thetas`

(as far as we set this line to zeros).

```
all.equal(lp.clm$eta1[1,1:3], fm.clm$alpha, check.attributes=FALSE)
# [1] TRUE
```

**Note 3:** We can *manually* construct such predictions. For instance, prediction for second line in `new.data`

:

```
second.line <- fm.clm$alpha - sum(fm.clm$beta*new.data[2,])
all.equal(lp.clm$eta1[2,1:3], second.line, check.attributes=FALSE)
# [1] TRUE
```

**Note 4:** If `new.data`

contains response variable, then `predict`

returns only linear predictor for specified level of `y`

. Again we can check it manually:

```
new.data$y <- gl(4,3,length=10)
lp.clm.y <- predict(fm.clm, new.data, type="linear.predictor")
lp.clm.y
lp.manual <- sapply(1:10, function(i) lp.clm$eta1[i,new.data$y[i]])
all.equal(lp.clm.y$eta1, lp.manual)
# [1] TRUE
```