# Why does constraining the intercepts not change the degrees of freedom?

This is caused by the fact that you are modelling growth curves: when you use the `growth()`

function in `lavaan`

, *all of the intercepts are automatically constrained to be zero!* This is why you are getting an identical output when you compare the "unconstrained" model to the one where you've constrained the intercepts - the models actually *are* identical.

To explore this a bit further, try using `sem()`

and not `growth()`

to run your model fits. We are going to use `sem()`

simply to get a better look at how the degrees of freedom change, as it does not automatically enforce any constraints on its own. Let's take a look at the degrees of freedom again:

```
> fitMeasures(fit_UNconstrained, "df")
df
416
> fitMeasures(fit_constrained_intercepts, "df")
df
434
```

Note that we gain 18 degrees of freedom by fixing the intercepts. I'll break this down as follows:

Your model has 20 observed variables (t1:t20), so we might think that we gain 20 degrees of freedom by fixing the intercept for each of these observed variables. However, we are actually constraining all of the intercepts to be identical *within each latent variable* (In this case, you have two latent variables, **i** and **s**). Instead of fitting 20 intercepts like before, we are instead fitting 2 intercepts (one for each latent variable), resulting in a net gain of 18 degrees of freedom.

# Why does constraining the variances change df by 2?

In your question you mentioned that:

*"...the difference in degrees of freedom is 2, not 1 as I would expect from constraining a single parameter..."*

Unfortunately, this isn't quite right. In SEM models, the degrees of freedom do not depend on the number of "types" of parameters that we are constraining, but rather they depend on the total number of "free parameters" in your model.

When you use `lv.variances`

, you are actually constraining the variance of the latent variables. As mentioned above, you have **two** latent variables, **i** and **s**, so you are constraining one parameter each, resulting in you gaining two degrees of freedom.

# SEM Degrees of Freedom, Further Explained:

Let's fit a small SEM, and then manually calculate the degrees of freedom. Since you're modelling growth curves, we'll use a simplified version of your own growth model. We're going to use three time points instead of twenty.

```
model_regressions <- ' i =~ 1*t1 + 1*t2 + 1*t3
s =~ 0*t1 + 1*t2 + 2*t3'
fit_UNconstrained <- growth(model_regressions, data=growth_data, group = "type")
summary(fit_UNconstrained) # note the use of "summary()" here
```

We can calculate the degrees of freedom directly using this formula:

**Degrees of Freedom = (the number of unique observations) - (the number of free parameters)**

**1.** Let's calculate the number of unique observations first:

For **your** growth models, the formula for the number of unique observations in each group is **k(k+1)/2 + k**, where **k** is the number of observed variables you have. This comes from the fact that you have **k(k+1)/2** covariances for your observed variables, and **k** observed means. In this case, you have 3 observed variables, so you have 3(3+1)/2 + 3 = 9 unique observations in each group. You also have two groups, so we actually have (9 * 2) = 18 observations in total.

**2.** Now onto the free parameters. We are fitting (for each group):

- 2 intercepts for all of the observed variables (can be viewed as 1 intercept for each latent variable)
- 3 variances for the observed variables
- 2 variances for the latent variables
- 1 covariance between the latent variables

This gives us 8 free parameters, but again, you have two groups, so (8 * 2) gives us 16 free parameters in total.

Using the formula stated above, 18 - 16 = 2 degrees of freedom. Let's see if `lavaan`

agrees:

```
> fit_UNconstrained
lavaan 0.6-3 ended normally after 64 iterations
Optimization method NLMINB
Number of free parameters 16
Number of observations per group
Exploration 87
Exploitation 125
Estimator ML
Model Fit Test Statistic 62.079
Degrees of freedom 2
P-value (Chi-square) 0.000
```

Voila! I hope this makes things clearer for you. Please keep in mind that if you chose to fix your regressions using `s ~ h_index`

etc., this will also change your degrees of freedom. In general, you should use `summary()`

to see how many free parameters you are estimating, and you can use `inspect(..., "sampstat")`

to get a look at how many unique observations you have.

I suggest playing around with some simpler SEM structures to get a better idea for how they work. Good luck, and happy modelling!

`growth_data`

?