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This package offers some helper functions to specify and analyse univariate and bivariate latent change score models (LCSM) using lavaan (Rosseel, 2012). For details about this method see for example McArdle (2009), Ghisletta (2012), Grimm et al. (2012), and Grimm, Ram & Estabrook (2017).
The lcsm
package combines the strengths of other R
packages like lavaan, broom, and semPlot by
generating lavaan syntax that helps these packages work together. This
is work in progress and feedback is very welcome!
You can install the released version of lcsm
from CRAN with:
install.packages("lcsm")
The development version can be installed from GitHub using:
# install.packages("devtools")
::install_github("milanwiedemann/lcsm") devtools
The lcsm
package contains the functions listed below. A
more detailed description of these functions is available in this README
or vignettes. The interactive online application shinychange
also illustrates some functions of this package.
specify_uni_lcsm()
: Generate syntax for univariate
LCSMspecify_bi_lcsm()
: Generate syntax for bivariate
LCSMfit_uni_lcsm()
: Fit univariate LCSMfit_bi_lcsm()
: Fit bivariate LCSMextract_fit()
: Extract fit statisticsextract_param()
: Extract estimated parameterssim_uni_lcsm()
: Simulate data by specifying parameters
for a univariate LCSMsim_bi_lcsm()
: Simulate data by specifying parameters
for a bivariate LCSMplot_lcsm()
: Visualise LCSM using semPlotselect_uni_cases()
: Select cases for analysis based on
available scores on one constructselect_bi_cases()
: Select cases for analysis based on
available scores on two constructlcsm
Here are a few examples how to use the lcsm
package.
# Load the package
library(lcsm)
#>
#> ── This is lcsm 0.3.1 ──────────────────────────────────────────────────────────
#> ℹ Please report any issues or ideas at:
#> ℹ https://github.com/milanwiedemann/lcsm/issues
#>
Longitudinal data can be visualised using the
plot_trajectories()
function. Here only 30% of the data is
visualised using the argument random_sample_frac = 0.3
.
Only consecutive measures are connected by lines as specified in
connect_missing = FALSE
.
# Create plot for construct x
<- plot_trajectories(data = data_bi_lcsm,
plot_x id_var = "id",
var_list = c("x1", "x2", "x3", "x4", "x5",
"x6", "x7", "x8", "x9", "x10"),
xlab = "Time", ylab = "X Score",
connect_missing = FALSE,
random_sample_frac = 0.3)
# Create plot for construct y
<- plot_trajectories(data = data_bi_lcsm,
plot_y id_var = "id",
var_list = c("y1", "y2", "y3", "y4", "y5",
"y6", "y7", "y8", "y9", "y10"),
xlab = "Time", ylab = "Y Score",
connect_missing = FALSE,
random_sample_frac = 0.3)
# Arrange plots next to each other using patchwork
library(patchwork)
+ plot_y + plot_annotation(tag_levels = 'A')
plot_x #> Warning: Removed 18 rows containing missing values (`geom_line()`).
#> Warning: Removed 85 rows containing missing values (`geom_point()`).
#> Warning: Removed 37 rows containing missing values (`geom_line()`).
#> Warning: Removed 172 rows containing missing values (`geom_point()`).
The functions fit_uni_lcsm()
and
fit_bi_lcsm()
can be used to fit univariate and bivariate
LCSM with different model specifications. In a first step, these two
function generate the user specified lavaan syntax by calling the
specify_uni_lcsm()
or specify_bi_lcsm()
functions.
The following table describes some of the different model
specifications that the model
arguments can take. More
detail can be found in the help files
help(fit_uni_lcsm)
.
Model specification | Description |
---|---|
alpha_constant | Constant change factor |
beta | Proportional change factor |
phi | Autoregression of change scores |
The example below shows how to specify a generic univariate latent
change score model using the function specify_uni_lcsm()
. A
table of the description of all parameters that can be estimated is
shown here.
specify_uni_lcsm(timepoints = 5,
var = "x",
change_letter = "g",
model = list(alpha_constant = TRUE,
beta = TRUE,
phi = TRUE))
lavaan
syntax specified above.
# Specify latent true scores
lx1 =~ 1 * x1
lx2 =~ 1 * x2
lx3 =~ 1 * x3
lx4 =~ 1 * x4
lx5 =~ 1 * x5
# Specify mean of latent true scores
lx1 ~ gamma_lx1 * 1
lx2 ~ 0 * 1
lx3 ~ 0 * 1
lx4 ~ 0 * 1
lx5 ~ 0 * 1
# Specify variance of latent true scores
lx1 ~~ sigma2_lx1 * lx1
lx2 ~~ 0 * lx2
lx3 ~~ 0 * lx3
lx4 ~~ 0 * lx4
lx5 ~~ 0 * lx5
# Specify intercept of obseved scores
x1 ~ 0 * 1
x2 ~ 0 * 1
x3 ~ 0 * 1
x4 ~ 0 * 1
x5 ~ 0 * 1
# Specify variance of observed scores
x1 ~~ sigma2_ux * x1
x2 ~~ sigma2_ux * x2
x3 ~~ sigma2_ux * x3
x4 ~~ sigma2_ux * x4
x5 ~~ sigma2_ux * x5
# Specify autoregressions of latent variables
lx2 ~ 1 * lx1
lx3 ~ 1 * lx2
lx4 ~ 1 * lx3
lx5 ~ 1 * lx4
# Specify latent change scores
dx2 =~ 1 * lx2
dx3 =~ 1 * lx3
dx4 =~ 1 * lx4
dx5 =~ 1 * lx5
# Specify latent change scores means
dx2 ~ 0 * 1
dx3 ~ 0 * 1
dx4 ~ 0 * 1
dx5 ~ 0 * 1
# Specify latent change scores variances
dx2 ~~ 0 * dx2
dx3 ~~ 0 * dx3
dx4 ~~ 0 * dx4
dx5 ~~ 0 * dx5
# Specify constant change factor
g2 =~ 1 * dx2 + 1 * dx3 + 1 * dx4 + 1 * dx5
# Specify constant change factor mean
g2 ~ alpha_g2 * 1
# Specify constant change factor variance
g2 ~~ sigma2_g2 * g2
# Specify constant change factor covariance with the initial true score
g2 ~~ sigma_g2lx1 * lx1
# Specify proportional change component
dx2 ~ beta_x * lx1
dx3 ~ beta_x * lx2
dx4 ~ beta_x * lx3
dx5 ~ beta_x * lx4
# Specify autoregression of change score
dx3 ~ phi_x * dx2
dx4 ~ phi_x * dx3
dx5 ~ phi_x * dx4
The function fit_uni_lcsm()
can be used to fit a
univariate LCSM using the sample data set data_uni_lcsm
.
This functions first writes the lavaan syntax specified in the
model
argument and passes it on to
lavaaan::lavaan()
.
# Fit univariate latent change score model
fit_uni_lcsm(data = data_uni_lcsm,
var = c("x1", "x2", "x3", "x4", "x5",
"x6", "x7", "x8", "x9", "x10"),
model = list(alpha_constant = TRUE,
beta = FALSE,
phi = TRUE))
#> lavaan 0.6.13 ended normally after 67 iterations
#>
#> Estimator ML
#> Optimization method NLMINB
#> Number of model parameters 23
#> Number of equality constraints 16
#>
#> Number of observations 500
#> Number of missing patterns 273
#>
#> Model Test User Model:
#> Standard Scaled
#> Test Statistic 75.389 74.400
#> Degrees of freedom 58 58
#> P-value (Chi-square) 0.062 0.072
#> Scaling correction factor 1.013
#> Yuan-Bentler correction (Mplus variant)
It is also possible to show the lavaan syntax that was created to fit
the model by the function specify_uni_lcsm()
. The lavaan
syntax includes comments describing some parts of the syntax in more
detail. To save the syntax in an object the argument
return_lavaan_syntax
has to be set to TRUE
.
This object looks a bit funny, it’s one very long line of text, but can
be formatted to look more beautiful and readable using
cat(syntax)
.
# Fit univariate latent change score model
<- fit_uni_lcsm(data = data_uni_lcsm,
syntax var = c("x1", "x2", "x3", "x4", "x5",
"x6", "x7", "x8", "x9", "x10"),
model = list(alpha_constant = TRUE,
beta = FALSE,
phi = TRUE),
return_lavaan_syntax = TRUE)
# Return lavaan syntax in easy to read format
cat(syntax)
syntax
.
# Specify latent true scores
lx1 =~ 1 * x1
lx2 =~ 1 * x2
lx3 =~ 1 * x3
lx4 =~ 1 * x4
lx5 =~ 1 * x5
lx6 =~ 1 * x6
lx7 =~ 1 * x7
lx8 =~ 1 * x8
lx9 =~ 1 * x9
lx10 =~ 1 * x10
# Specify mean of latent true scores
lx1 ~ gamma_lx1 * 1
lx2 ~ 0 * 1
lx3 ~ 0 * 1
lx4 ~ 0 * 1
lx5 ~ 0 * 1
lx6 ~ 0 * 1
lx7 ~ 0 * 1
lx8 ~ 0 * 1
lx9 ~ 0 * 1
lx10 ~ 0 * 1
# Specify variance of latent true scores
lx1 ~~ sigma2_lx1 * lx1
lx2 ~~ 0 * lx2
lx3 ~~ 0 * lx3
lx4 ~~ 0 * lx4
lx5 ~~ 0 * lx5
lx6 ~~ 0 * lx6
lx7 ~~ 0 * lx7
lx8 ~~ 0 * lx8
lx9 ~~ 0 * lx9
lx10 ~~ 0 * lx10
# Specify intercept of obseved scores
x1 ~ 0 * 1
x2 ~ 0 * 1
x3 ~ 0 * 1
x4 ~ 0 * 1
x5 ~ 0 * 1
x6 ~ 0 * 1
x7 ~ 0 * 1
x8 ~ 0 * 1
x9 ~ 0 * 1
x10 ~ 0 * 1
# Specify variance of observed scores
x1 ~~ sigma2_ux * x1
x2 ~~ sigma2_ux * x2
x3 ~~ sigma2_ux * x3
x4 ~~ sigma2_ux * x4
x5 ~~ sigma2_ux * x5
x6 ~~ sigma2_ux * x6
x7 ~~ sigma2_ux * x7
x8 ~~ sigma2_ux * x8
x9 ~~ sigma2_ux * x9
x10 ~~ sigma2_ux * x10
# Specify autoregressions of latent variables
lx2 ~ 1 * lx1
lx3 ~ 1 * lx2
lx4 ~ 1 * lx3
lx5 ~ 1 * lx4
lx6 ~ 1 * lx5
lx7 ~ 1 * lx6
lx8 ~ 1 * lx7
lx9 ~ 1 * lx8
lx10 ~ 1 * lx9
# Specify latent change scores
dx2 =~ 1 * lx2
dx3 =~ 1 * lx3
dx4 =~ 1 * lx4
dx5 =~ 1 * lx5
dx6 =~ 1 * lx6
dx7 =~ 1 * lx7
dx8 =~ 1 * lx8
dx9 =~ 1 * lx9
dx10 =~ 1 * lx10
# Specify latent change scores means
dx2 ~ 0 * 1
dx3 ~ 0 * 1
dx4 ~ 0 * 1
dx5 ~ 0 * 1
dx6 ~ 0 * 1
dx7 ~ 0 * 1
dx8 ~ 0 * 1
dx9 ~ 0 * 1
dx10 ~ 0 * 1
# Specify latent change scores variances
dx2 ~~ 0 * dx2
dx3 ~~ 0 * dx3
dx4 ~~ 0 * dx4
dx5 ~~ 0 * dx5
dx6 ~~ 0 * dx6
dx7 ~~ 0 * dx7
dx8 ~~ 0 * dx8
dx9 ~~ 0 * dx9
dx10 ~~ 0 * dx10
# Specify constant change factor
g2 =~ 1 * dx2 + 1 * dx3 + 1 * dx4 + 1 * dx5 + 1 * dx6 + 1 * dx7 + 1 * dx8 + 1 * dx9 + 1 * dx10
# Specify constant change factor mean
g2 ~ alpha_g2 * 1
# Specify constant change factor variance
g2 ~~ sigma2_g2 * g2
# Specify constant change factor covariance with the initial true score
g2 ~~ sigma_g2lx1 * lx1
# Specify autoregression of change score
dx3 ~ phi_x * dx2
dx4 ~ phi_x * dx3
dx5 ~ phi_x * dx4
dx6 ~ phi_x * dx5
dx7 ~ phi_x * dx6
dx8 ~ phi_x * dx7
dx9 ~ phi_x * dx8
dx10 ~ phi_x * dx9
The function fit_bi_lcsm()
allows to specify two
univariate LCSMs using the arguments model_x
and
model_x
. These two constructs can then be connected using
the coupling
argument. More details can be found in the
help files help(fit_bi_lcsm)
.
Coupling specification | Description |
---|---|
coupling_piecewise | Piecewise coupling parameters |
coupling_piecewise_num | Changepoint of piecewise coupling parameters |
delta_con_xy | Change score x (t) determined by true score y (t) |
delta_con_yx | Change score y (t) determined by true score x (t) |
delta_lag_xy | Change score x (t) determined by true score y (t-1) |
delta_lag_yx | Change score y (t) determined by true score x (t-1) |
xi_con_xy | Change score x (t) determined by change score y (t) |
xi_con_yx | Change score y (t) determined by change score x (t) |
xi_lag_xy | Change score x (t) determined by change score y (t-1) |
xi_lag_yx | Change score y (t) determined by change score x (t-1) |
fit_bi_lcsm(data = data_bi_lcsm,
var_x = c("x1", "x2", "x3", "x4", "x5",
"x6", "x7", "x8", "x9", "x10"),
var_y = c("y1", "y2", "y3", "y4", "y5",
"y6", "y7", "y8", "y9", "y10"),
model_x = list(alpha_constant = TRUE,
beta = TRUE,
phi = FALSE),
model_y = list(alpha_constant = TRUE,
beta = TRUE,
phi = TRUE),
coupling = list(delta_lag_xy = TRUE,
xi_lag_yx = TRUE))
#> lavaan 0.6.13 ended normally after 114 iterations
#>
#> Estimator ML
#> Optimization method NLMINB
#> Number of model parameters 87
#> Number of equality constraints 65
#>
#> Number of observations 500
#> Number of missing patterns 210
#>
#> Model Test User Model:
#> Standard Scaled
#> Test Statistic 191.851 193.021
#> Degrees of freedom 208 208
#> P-value (Chi-square) 0.782 0.764
#> Scaling correction factor 0.994
#> Yuan-Bentler correction (Mplus variant)
The main underlying functions to extract parameters and fit
statistics come from the broom
package:
broom::tidy()
and broom::glance()
. The
functions extract_param()
and extract_fit()
offer some tools that I find helpful when running LCSMs in R, for
example:
extract_param()
: only one row per estimated
parameter,extract_fit()
: fit statistics for multiple lavaan
objects can be extracted.A table of the description of all parameters that can be estimated is shown here.
# First create a lavaan object
<- fit_bi_lcsm(data = data_bi_lcsm,
bi_lcsm_01 var_x = c("x1", "x2", "x3", "x4", "x5",
"x6", "x7", "x8", "x9", "x10"),
var_y = c("y1", "y2", "y3", "y4", "y5",
"y6", "y7", "y8", "y9", "y10"),
model_x = list(alpha_constant = TRUE,
beta = TRUE,
phi = FALSE),
model_y = list(alpha_constant = TRUE,
beta = TRUE,
phi = TRUE),
coupling = list(delta_lag_xy = TRUE,
xi_lag_yx = TRUE))
# Now extract parameter estimates
# Only extract first 7 columns for this example by adding [ , 1:7]
<- extract_param(bi_lcsm_01, printp = TRUE)[ , 1:7]
param_bi_lcsm_01
# Print table of parameter estimates
kable(param_bi_lcsm_01, digits = 3)
label | estimate | std.error | statistic | p.value | std.lv | std.all |
---|---|---|---|---|---|---|
gamma_lx1 | 21.066 | 0.036 | 588.187 | < .001 | 30.014 | 30.014 |
sigma2_lx1 | 0.493 | 0.037 | 13.485 | < .001 | 1.000 | 1.000 |
sigma2_ux | 0.201 | 0.004 | 45.301 | < .001 | 0.201 | 0.290 |
alpha_g2 | -0.309 | 0.053 | -5.834 | < .001 | -0.492 | -0.492 |
sigma2_g2 | 0.395 | 0.028 | 14.330 | < .001 | 1.000 | 1.000 |
sigma_g2lx1 | 0.155 | 0.022 | 7.017 | < .001 | 0.351 | 0.351 |
beta_x | -0.106 | 0.003 | -30.818 | < .001 | -0.120 | -0.120 |
gamma_ly1 | 5.025 | 0.029 | 172.786 | < .001 | 11.009 | 11.009 |
sigma2_ly1 | 0.208 | 0.019 | 10.860 | < .001 | 1.000 | 1.000 |
sigma2_uy | 0.193 | 0.005 | 39.698 | < .001 | 0.193 | 0.481 |
alpha_j2 | -0.203 | 0.039 | -5.217 | < .001 | -0.666 | -0.666 |
sigma2_j2 | 0.093 | 0.008 | 11.766 | < .001 | 1.000 | 1.000 |
sigma_j2ly1 | 0.017 | 0.008 | 2.156 | .031 | 0.122 | 0.122 |
beta_y | -0.197 | 0.005 | -39.562 | < .001 | -0.293 | -0.293 |
phi_y | 0.144 | 0.029 | 4.963 | < .001 | 0.126 | 0.126 |
sigma_su | 0.009 | 0.003 | 2.581 | .01 | 0.009 | 0.044 |
sigma_ly1lx1 | 0.185 | 0.021 | 8.905 | < .001 | 0.577 | 0.577 |
sigma_g2ly1 | 0.072 | 0.016 | 4.437 | < .001 | 0.251 | 0.251 |
sigma_j2lx1 | 0.093 | 0.012 | 7.916 | < .001 | 0.437 | 0.437 |
sigma_j2g2 | 0.005 | 0.012 | 0.463 | .643 | 0.029 | 0.029 |
delta_lag_xy | 0.140 | 0.006 | 23.837 | < .001 | 0.103 | 0.103 |
xi_lag_yx | 0.360 | 0.037 | 9.634 | < .001 | 0.640 | 0.640 |
This function is work in progress and can only plot univariate and
bivariate LCSMs that were specified with fit_uni_lcsm()
or
fit_bi_lcsm()
. Modified LCSMs will probably return errors
as the layout matrix that gets created by this plot function only
supports the specifications that can be modelled with this package. The
input arguments for plotting a simplified path diagram are:
lavaan_object
,lavaan_syntax
and ,lcsm
indicating whether the LCSMs is “univariate” or
“bivariate”Optional arguments can be used to change the look of the plot, for example:
lcsm_colours
can be used to highlight the different
parts of the latent change score model
Further arguments can be passed on to
semPlot::semPaths()
, for example:
what
, “path” to show unweighted gray
edges, “par” to show parameter estimates as weighted
(green/red) edgeswhatLabels
, “label” to show edege
names as label or “est” for parameter estimates,
“hide” to hide edge labels# Fit bivariate lcsm and save the results
<- fit_uni_lcsm(data = data_uni_lcsm,
uni_lavaan_results var = c("x1", "x2", "x3", "x4", "x5"),
model = list(alpha_constant = TRUE,
beta = TRUE,
phi = TRUE)
)#> Warning in lav_data_full(data = data, group = group, cluster = cluster, : lavaan WARNING: some cases are empty and will be ignored:
#> 239
# Save the lavaan syntax that is used to create the layout matrix for semPlot
<- fit_uni_lcsm(data = data_uni_lcsm,
uni_lavaan_syntax var = c("x1", "x2", "x3", "x4", "x5"),
model = list(alpha_constant = TRUE,
beta = TRUE,
phi = TRUE),
return_lavaan_syntax = TRUE)
# Plot the results
plot_lcsm(lavaan_object = uni_lavaan_results,
lavaan_syntax = uni_lavaan_syntax,
edge.label.cex = .9,
lcsm_colours = TRUE,
lcsm = "univariate")
# Fit bivariate lcsm and save the results
<- fit_bi_lcsm(data = data_bi_lcsm,
bi_lavaan_results var_x = c("x1", "x2", "x3", "x4", "x5"),
var_y = c("y1", "y2", "y3", "y4", "y5"),
model_x = list(alpha_constant = TRUE,
beta = TRUE,
phi = FALSE),
model_y = list(alpha_constant = TRUE,
beta = TRUE,
phi = TRUE),
coupling = list(delta_lag_xy = TRUE,
xi_lag_yx = TRUE))
# Save the lavaan syntax that is used to create the layout matrix for semPlot
<- fit_bi_lcsm(data = data_bi_lcsm,
bi_lavaan_syntax var_x = c("x1", "x2", "x3", "x4", "x5"),
var_y = c("y1", "y2", "y3", "y4", "y5"),
model_x = list(alpha_constant = TRUE,
beta = TRUE,
phi = FALSE),
model_y = list(alpha_constant = TRUE,
beta = TRUE,
phi = TRUE),
coupling = list(delta_lag_xy = TRUE,
xi_lag_yx = TRUE),
return_lavaan_syntax = TRUE)
# Plot the results
plot_lcsm(lavaan_object = bi_lavaan_results,
lavaan_syntax = bi_lavaan_syntax,
lcsm_colours = TRUE,
whatLabels = "hide",
lcsm = "bivariate")
The functions sim_uni_lcsm()
and
sim_bi_lcsm()
simulate data based on some some parameters
that can be specified. See the tables here for a full
list of parameters that can be specified for the data simulation.
# Simulate some data
sim_uni_lcsm(timepoints = 5,
model = list(alpha_constant = TRUE, beta = FALSE, phi = TRUE),
model_param = list(gamma_lx1 = 21,
sigma2_lx1 = 1.5,
sigma2_ux = 0.2,
alpha_j2 = -0.93,
sigma2_j2 = 0.1,
sigma_j2lx1 = 0.2,
phi_x = 0.3),
sample.nobs = 1000,
na_pct = 0.3)
#> Parameter estimates for the data simulation are taken from the argument 'model_param'.
#> Warning: The following parameters are specified in the LCSM but no parameter estimates have been entered in 'model_param':
#> - alpha_g2
#> - sigma2_g2
#> - sigma_g2lx1
#> # A tibble: 1,000 × 6
#> id x1 x2 x3 x4 x5
#> <int> <dbl> <dbl> <dbl> <dbl> <dbl>
#> 1 1 21.8 20.4 18.0 15.3 NA
#> 2 2 22.5 22.7 NA 19.0 NA
#> 3 3 22.3 21.4 20.5 18.8 18.5
#> 4 4 NA NA 21.9 25.0 25.9
#> 5 5 18.8 18.4 18.9 18.8 NA
#> 6 6 20.0 19.1 17.1 15.5 13.8
#> 7 7 20.1 18.6 16.9 NA NA
#> 8 8 22.3 23.2 22.6 23.6 25.3
#> 9 9 18.7 NA 19.3 19.5 19.8
#> 10 10 NA 22.3 NA 22.2 22.4
#> # … with 990 more rows
It is also possible to return the lavaan syntax instead of simulating
data for further manual specifications. The modified object could then
be used to simulate data using lavaan::simulateData()
.
# Return lavaan syntax based on the following argument specifications
<- sim_bi_lcsm(timepoints = 5,
simsyntax model_x = list(alpha_constant = TRUE, beta = TRUE, phi = FALSE),
model_x_param = list(gamma_lx1 = 21,
sigma2_lx1 = .5,
sigma2_ux = .2,
alpha_g2 = -.4,
sigma2_g2 = .4,
sigma_g2lx1 = .2,
beta_x = -.1),
model_y = list(alpha_constant = TRUE, beta = TRUE, phi = TRUE),
model_y_param = list(gamma_ly1 = 5,
sigma2_ly1 = .2,
sigma2_uy = .2,
alpha_j2 = -.2,
sigma2_j2 = .1,
sigma_j2ly1 = .02,
beta_y = -.2,
phi_y = .1),
coupling = list(delta_lag_xy = TRUE,
xi_lag_yx = TRUE),
coupling_param = list(sigma_su = .01,
sigma_ly1lx1 = .2,
sigma_g2ly1 = .1,
sigma_j2lx1 = .1,
sigma_j2g2 = .01,
delta_lag_xy = .13,
xi_lag_yx = .4),
return_lavaan_syntax = TRUE)
simsyntax
.
# Specify parameters for construct x ----
# Specify latent true scores
lx1 =~ 1 * x1
lx2 =~ 1 * x2
lx3 =~ 1 * x3
lx4 =~ 1 * x4
lx5 =~ 1 * x5
# Specify mean of latent true scores
lx1 ~ 21 * 1
lx2 ~ 0 * 1
lx3 ~ 0 * 1
lx4 ~ 0 * 1
lx5 ~ 0 * 1
# Specify variance of latent true scores
lx1 ~~ 0.5 * lx1
lx2 ~~ 0 * lx2
lx3 ~~ 0 * lx3
lx4 ~~ 0 * lx4
lx5 ~~ 0 * lx5
# Specify intercept of obseved scores
x1 ~ 0 * 1
x2 ~ 0 * 1
x3 ~ 0 * 1
x4 ~ 0 * 1
x5 ~ 0 * 1
# Specify variance of observed scores
x1 ~~ 0.2 * x1
x2 ~~ 0.2 * x2
x3 ~~ 0.2 * x3
x4 ~~ 0.2 * x4
x5 ~~ 0.2 * x5
# Specify autoregressions of latent variables
lx2 ~ 1 * lx1
lx3 ~ 1 * lx2
lx4 ~ 1 * lx3
lx5 ~ 1 * lx4
# Specify latent change scores
dx2 =~ 1 * lx2
dx3 =~ 1 * lx3
dx4 =~ 1 * lx4
dx5 =~ 1 * lx5
# Specify latent change scores means
dx2 ~ 0 * 1
dx3 ~ 0 * 1
dx4 ~ 0 * 1
dx5 ~ 0 * 1
# Specify latent change scores variances
dx2 ~~ 0 * dx2
dx3 ~~ 0 * dx3
dx4 ~~ 0 * dx4
dx5 ~~ 0 * dx5
# Specify constant change factor
g2 =~ 1 * dx2 + 1 * dx3 + 1 * dx4 + 1 * dx5
# Specify constant change factor mean
g2 ~ -0.4 * 1
# Specify constant change factor variance
g2 ~~ 0.4 * g2
# Specify constant change factor covariance with the initial true score
g2 ~~ 0.2 * lx1
# Specify proportional change component
dx2 ~ -0.1 * lx1
dx3 ~ -0.1 * lx2
dx4 ~ -0.1 * lx3
dx5 ~ -0.1 * lx4
# Specify parameters for construct y ----
# Specify latent true scores
ly1 =~ 1 * y1
ly2 =~ 1 * y2
ly3 =~ 1 * y3
ly4 =~ 1 * y4
ly5 =~ 1 * y5
# Specify mean of latent true scores
ly1 ~ 5 * 1
ly2 ~ 0 * 1
ly3 ~ 0 * 1
ly4 ~ 0 * 1
ly5 ~ 0 * 1
# Specify variance of latent true scores
ly1 ~~ 0.2 * ly1
ly2 ~~ 0 * ly2
ly3 ~~ 0 * ly3
ly4 ~~ 0 * ly4
ly5 ~~ 0 * ly5
# Specify intercept of obseved scores
y1 ~ 0 * 1
y2 ~ 0 * 1
y3 ~ 0 * 1
y4 ~ 0 * 1
y5 ~ 0 * 1
# Specify variance of observed scores
y1 ~~ 0.2 * y1
y2 ~~ 0.2 * y2
y3 ~~ 0.2 * y3
y4 ~~ 0.2 * y4
y5 ~~ 0.2 * y5
# Specify autoregressions of latent variables
ly2 ~ 1 * ly1
ly3 ~ 1 * ly2
ly4 ~ 1 * ly3
ly5 ~ 1 * ly4
# Specify latent change scores
dy2 =~ 1 * ly2
dy3 =~ 1 * ly3
dy4 =~ 1 * ly4
dy5 =~ 1 * ly5
# Specify latent change scores means
dy2 ~ 0 * 1
dy3 ~ 0 * 1
dy4 ~ 0 * 1
dy5 ~ 0 * 1
# Specify latent change scores variances
dy2 ~~ 0 * dy2
dy3 ~~ 0 * dy3
dy4 ~~ 0 * dy4
dy5 ~~ 0 * dy5
# Specify constant change factor
j2 =~ 1 * dy2 + 1 * dy3 + 1 * dy4 + 1 * dy5
# Specify constant change factor mean
j2 ~ -0.2 * 1
# Specify constant change factor variance
j2 ~~ 0.1 * j2
# Specify constant change factor covariance with the initial true score
j2 ~~ 0.02 * ly1
# Specify proportional change component
dy2 ~ -0.2 * ly1
dy3 ~ -0.2 * ly2
dy4 ~ -0.2 * ly3
dy5 ~ -0.2 * ly4
# Specify autoregression of change score
dy3 ~ 0.1 * dy2
dy4 ~ 0.1 * dy3
dy5 ~ 0.1 * dy4
# Specify residual covariances
x1 ~~ 0.01 * y1
x2 ~~ 0.01 * y2
x3 ~~ 0.01 * y3
x4 ~~ 0.01 * y4
x5 ~~ 0.01 * y5
# Specify covariances betweeen specified change components (alpha) and intercepts (initial latent true scores lx1 and ly1) ----
# Specify covariance of intercepts
lx1 ~~ 0.2 * ly1
# Specify covariance of constant change and intercept within the same construct
ly1 ~~ 0.1 * g2
# Specify covariance of constant change and intercept within the same construct
lx1 ~~ 0.1 * j2
# Specify covariance of constant change factors between constructs
g2 ~~ 0.01 * j2
# Specify between-construct coupling parameters ----
# Change score x (t) is determined by true score y (t-1)
dx2 ~ 0.13 * ly1
dx3 ~ 0.13 * ly2
dx4 ~ 0.13 * ly3
dx5 ~ 0.13 * ly4
# Change score y (t) is determined by change score x (t-1)
dy3 ~ 0.4 * dx2
dy4 ~ 0.4 * dx3
dy5 ~ 0.4 * dx4
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They may not be fully stable and should be used with caution. We make no claims about them.
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