lessSEM (lessSEM estimates sparse SEM) is an R package for regularized structural equation modeling (regularized SEM) with non-smooth penalty functions (e.g., lasso) building on lavaan. lessSEM is heavily inspired by the regsem package and the lslx packages that have similar functionality. If you use lessSEM, please also cite regsem and and lslx!
The objectives of lessSEM are to provide …
- a flexible framework for regularizing SEM.
- optimizers for other packages that can handle non-differentiable penalty functions.
The following penalty functions are currently implemented in lessSEM:
The column “penalty” refers to the name of the function call in the
lessSEM package (e.g., lasso is called with the lasso()
function).
The best model can be selected with the AIC or BIC. If you want to use
cross-validation, use cvLasso
, cvAdaptiveLasso
, etc. instead (see,
e.g., ?lessSEM::cvLasso
).
The packages regsem, lslx, and lessSEM can all be used to regularize basic SEM. In fact, as outlined above, lessSEM is heavily inspired by regsem and lslx. However, the packages differ in their targets: The objective of lessSEM is not to replace the more mature packages regsem and lslx. Instead, our objective is to provide method developers with a flexible framework for regularized SEM. The following shows an incomplete comparison of some features implemented in the three packages:
regsem | lslx | lessSEM | |
---|---|---|---|
Model specification | based on lavaan | similar to lavaan | based on lavaan |
Maximum likelihood estimation | Yes | Yes | Yes |
Least squares estimation | No | Yes | Dev. |
Categorical variables | No | Yes | No |
Confidence Intervals | No | Yes | No |
Missing Data | FIML | Auxiliary Variables | FIML |
Multi-group models | No | Yes | Yes |
Stability selection | Yes | No | Dev. |
Mixed penalties | No | No | Yes |
Equality constraints | Yes | No | Yes |
Parameter transformations | diff_lasso | No | Yes |
Definition variables | No | No | Yes |
Warning Dev. refers to features that are supported, but still under development and may have bugs. Use with caution!
If you want to install lessSEM from CRAN, use the following commands in R:
install.packages("lessSEM")
The newest version of the package can be installed from GitHub. However,
because the project uses submodules, devtools::install_github
does not
download the entire R package. To download the development version, the
following command needs to be run in git:
git clone --branch development --recurse-submodules https://github.com/jhorzek/lessSEM.git
Navigate to the folder to which git copied the project and install the package with the lessSEM.Rproj file.
If you want to download the main branch, use
git clone --recurse-submodules https://github.com/jhorzek/lessSEM.git
Note The lessSEM project has multiple branches. The main branch will match the version currently available from CRAN. The development branch will have newer features not yet available from CRAN. This branch will have passed all current tests of our test suite, but may not be ready for CRAN yet (e.g., because not all objectives of the road map have been met). gh-pages is used to create the documentation website. Finally, all other branches are used for ongoing development and should be considered unstable.
Please visit the lessSEM website
for the latest documentation. You will also find a short introduction to
regularized SEM in vignette('lessSEM', package = 'lessSEM')
and the
documentation of the individual functions (e.g., see ?lessSEM::scad
).
Finally, you will find templates for a selection of models that can be
used with lessSEM (e.g., the cross-lagged panel model) in the
package lessTemplates.
library(lessSEM)
library(lavaan)
# Identical to regsem, lessSEM builds on the lavaan
# package for model specification. The first step
# therefore is to implement the model in lavaan.
dataset <- simulateExampleData()
lavaanSyntax <- "
f =~ l1*y1 + l2*y2 + l3*y3 + l4*y4 + l5*y5 +
l6*y6 + l7*y7 + l8*y8 + l9*y9 + l10*y10 +
l11*y11 + l12*y12 + l13*y13 + l14*y14 + l15*y15
f ~~ 1*f
"
lavaanModel <- lavaan::sem(lavaanSyntax,
data = dataset,
meanstructure = TRUE,
std.lv = TRUE)
# Optional: Plot the model
# if(!require("semPlot")) install.packages("semPlot")
# semPlot::semPaths(lavaanModel,
# what = "est",
# fade = FALSE)
lsem <- lasso(
# pass the fitted lavaan model
lavaanModel = lavaanModel,
# names of the regularized parameters:
regularized = c("l6", "l7", "l8", "l9", "l10",
"l11", "l12", "l13", "l14", "l15"),
# in case of lasso and adaptive lasso, we can specify the number of lambda
# values to use. lessSEM will automatically find lambda_max and fit
# models for nLambda values between 0 and lambda_max. For the other
# penalty functions, lambdas must be specified explicitly
nLambdas = 50)
# use the plot-function to plot the regularized parameters:
plot(lsem)
# use the coef-function to show the estimates
coef(lsem)
# the best parameters can be extracted with:
coef(lsem, criterion = "AIC")
coef(lsem, criterion = "BIC")
# if you just want the estimates, use estimates():
estimates(lsem, criterion = "AIC")
# elements of lsem can be accessed with the @ operator:
lsem@parameters[1,]
# AIC and BIC for all tuning parameter configurations:
AIC(lsem)
BIC(lsem)
# cross-validation
cv <- cvLasso(lavaanModel = lavaanModel,
regularized = c("l6", "l7", "l8", "l9", "l10",
"l11", "l12", "l13", "l14", "l15"),
lambdas = seq(0,1,.1),
standardize = TRUE)
# get best model according to cross-validation:
coef(cv)
#### Advanced ####
# Switching the optimizer:
# Use the "method" argument to switch the optimizer. The control argument
# must also be changed to the corresponding function:
lsemIsta <- lasso(
lavaanModel = lavaanModel,
regularized = paste0("l", 6:15),
nLambdas = 50,
method = "ista",
control = controlIsta(
# Here, we can also specify that we want to use multiple cores:
nCores = 2))
# Note: The results are basically identical:
lsemIsta@parameters - lsem@parameters
If you want to regularize all loadings, regressions, variances, or covariances, you can also use one of the helper functions to extract the respective parameter labels from lavaan and then pass these to lessSEM:
loadings(lavaanModel)
#> [1] "l1" "l2" "l3" "l4" "l5" "l6" "l7" "l8" "l9" "l10" "l11" "l12"
#> [13] "l13" "l14" "l15"
regressions(lavaanModel)
#> character(0)
variances(lavaanModel)
#> [1] "y1~~y1" "y2~~y2" "y3~~y3" "y4~~y4" "y5~~y5" "y6~~y6"
#> [7] "y7~~y7" "y8~~y8" "y9~~y9" "y10~~y10" "y11~~y11" "y12~~y12"
#> [13] "y13~~y13" "y14~~y14" "y15~~y15"
covariances(lavaanModel)
#> character(0)
lessSEM allows for parameter transformations that could, for
instance, be used to test measurement invariance in longitudinal models
(e.g., Liang, 2018; Bauer et al., 2020). A thorough introduction is
provided in
vignette('Parameter-transformations', package = 'lessSEM')
. As an
example, we will test measurement invariance in the PoliticalDemocracy
data set.
library(lessSEM)
library(lavaan)
# we will use the PoliticalDemocracy from lavaan (see ?lavaan::sem)
model <- '
# latent variable definitions
ind60 =~ x1 + x2 + x3
# assuming different loadings for different time points:
dem60 =~ y1 + a1*y2 + b1*y3 + c1*y4
dem65 =~ y5 + a2*y6 + b2*y7 + c2*y8
# regressions
dem60 ~ ind60
dem65 ~ ind60 + dem60
# residual correlations
y1 ~~ y5
y2 ~~ y4 + y6
y3 ~~ y7
y4 ~~ y8
y6 ~~ y8
'
fit <- sem(model, data = PoliticalDemocracy)
# We will define a transformation which regularizes differences
# between loadings over time:
transformations <- "
// which parameters do we want to use?
parameters: a1, a2, b1, b2, c1, c2, delta_a2, delta_b2, delta_c2
// transformations:
a2 = a1 + delta_a2;
b2 = b1 + delta_b2;
c2 = c1 + delta_c2;
"
# setting delta_a2, delta_b2, or delta_c2 to zero implies measurement invariance
# for the respective parameters (a1, b1, c1)
lassoFit <- lasso(lavaanModel = fit,
# we want to regularize the differences between the parameters
regularized = c("delta_a2", "delta_b2", "delta_c2"),
nLambdas = 100,
# Our model modification must make use of the modifyModel - function:
modifyModel = modifyModel(transformations = transformations)
)
Finally, we can extract the best parameters:
coef(lassoFit, criterion = "BIC")
As all differences (delta_a2
, delta_b2
, and delta_c2
) have been
zeroed, we can assume measurement invariance.
The following features are relatively new and you may still experience some bugs. Please be aware of that when using these features.
lessSEM supports exporting specific models to lavaan. This can be very useful when plotting the final model.
lavaanModel <- lessSEM2Lavaan(regularizedSEM = lsem,
criterion = "BIC")
The result can be plotted with, for instance, semPlot:
library(semPlot)
semPaths(lavaanModel,
what = "est",
fade = FALSE)
lessSEM supports multi-group SEM and, to some degree, definition
variables. Regularized multi-group SEM have been proposed by Huang
(2018) and are implemented in lslx (Huang, 2020). Here, differences
between groups are regularized. A detailed introduction can be found in
vignette(topic = "Definition-Variables-and-Multi-Group-SEM", package = "lessSEM")
.
Therein it is also explained how the multi-group SEM can be used to
implement definition variables (e.g., for latent growth curve models).
lessSEM allows for defining different penalties for different parts
of the model. This feature is new and very experimental. Please keep
that in mind when using the procedure. A detailed introduction can be
found in vignette(topic = "Mixed-Penalties", package = "lessSEM")
.
To provide a short example, we will regularize the loadings and the
regression parameters of the Political Democracy data set with different
penalties. The following script is adapted from ?lavaan::sem
.
model <- '
# latent variable definitions
ind60 =~ x1 + x2 + x3 + c2*y2 + c3*y3 + c4*y4
dem60 =~ y1 + y2 + y3 + y4
dem65 =~ y5 + y6 + y7 + c*y8
# regressions
dem60 ~ r1*ind60
dem65 ~ r2*ind60 + r3*dem60
'
lavaanModel <- sem(model,
data = PoliticalDemocracy)
# Let's add a lasso penalty on the cross-loadings c2 - c4 and
# scad penalty on the regressions r1-r3
fitMp <- lavaanModel |>
mixedPenalty() |>
addLasso(regularized = c("c2", "c3", "c4"),
lambdas = seq(0,1,.1)) |>
addScad(regularized = c("r1", "r2", "r3"),
lambdas = seq(0,1,.2),
thetas = 3.7) |>
fit()
The best model according to the BIC can be extracted with:
coef(fitMp, criterion = "BIC")
Currently, lessSEM has the following optimizers:
- (variants of) iterative shrinkage and thresholding (e.g., Beck & Teboulle, 2009; Gong et al., 2013; Parikh & Boyd, 2013); optimization of cappedL1, lsp, scad, and mcp is based on Gong et al. (2013)
- glmnet (Friedman et al., 2010; Yuan et al., 2012; Huang, 2020)
These optimizers are implemented based on the
regCtsem package. Most
importantly, all optimizers in lessSEM are available for other
packages. There are four ways to implement them which are documented
in vignette("General-Purpose-Optimization", package = "lessSEM")
. In
short, these are:
- using the R interface: All general purpose implementations of the
functions are called with prefix “gp” (
gpLasso
,gpScad
, …). More information and examples can be found in the documentation of these functions (e.g.,?lessSEM::gpLasso
,?lessSEM::gpAdaptiveLasso
,?lessSEM::gpElasticNet
). The interface is similar to the optim optimizers in R. - using Rcpp, we can pass C++ function pointers to the general purpose
optimizers
gpLassoCpp
,gpScadCpp
, … (e.g.,?lessSEM::gpLassoCpp
) - All optimizers are implemented as C++ header-only files in
lessSEM. Thus, they can be accessed from other packages using
C++. The interface is similar to that of the
ensmallen library. We have implemented
a simple example for elastic net regularization of linear
regressions in the lessLM
package. You can also find more details on the general design of the
optimizer interface in
vignette("The-optimizer-interface", package = "lessSEM")
. - The optimizers are implemented in the separate C++ header only library lesstimate that can be used as a submodule in R packages.
- lavaan Rosseel, Y. (2012). lavaan: An R Package for Structural Equation Modeling. Journal of Statistical Software, 48(2), 1-36. https://doi.org/10.18637/jss.v048.i02
- regsem: Jacobucci, R. (2017). regsem: Regularized Structural Equation Modeling. ArXiv:1703.08489 [Stat]. https://arxiv.org/abs/1703.08489
- lslx: Huang, P.-H. (2020). lslx: Semi-confirmatory structural equation modeling via penalized likelihood. Journal of Statistical Software, 93(7). https://doi.org/10.18637/jss.v093.i07
- fasta: Another implementation of the fista algorithm (Beck & Teboulle, 2009).
- ensmallen: Curtin, R. R., Edel, M., Prabhu, R. G., Basak, S., Lou, Z., & Sanderson, C. (2021). The ensmallen library for flexible numerical optimization. Journal of Machine Learning Research, 22, 1–6.
- regCtsem: Orzek, J. H., & Voelkle, M. C. (in press). Regularized continuous time structural equation models: A network perspective. Psychological Methods.
- Huang, P.-H., Chen, H., & Weng, L.-J. (2017). A Penalized Likelihood Method for Structural Equation Modeling. Psychometrika, 82(2), 329–354. https://doi.org/10.1007/s11336-017-9566-9
- Huang, P.-H. (2018). A penalized likelihood method for multi-group structural equation modelling. British Journal of Mathematical and Statistical Psychology, 71(3), 499–522. https://doi.org/10.1111/bmsp.12130
- Jacobucci, R., Grimm, K. J., & McArdle, J. J. (2016). Regularized Structural Equation Modeling. Structural Equation Modeling: A Multidisciplinary Journal, 23(4), 555–566. https://doi.org/10.1080/10705511.2016.1154793
- Candès, E. J., Wakin, M. B., & Boyd, S. P. (2008). Enhancing Sparsity by Reweighted l1 Minimization. Journal of Fourier Analysis and Applications, 14(5–6), 877–905. https://doi.org/10.1007/s00041-008-9045-x
- Fan, J., & Li, R. (2001). Variable selection via nonconcave penalized likelihood and its oracle properties. Journal of the American Statistical Association, 96(456), 1348–1360. https://doi.org/10.1198/016214501753382273
- Hoerl, A. E., & Kennard, R. W. (1970). Ridge Regression: Biased Estimation for Nonorthogonal Problems. Technometrics, 12(1), 55–67. https://doi.org/10.1080/00401706.1970.10488634
- Tibshirani, R. (1996). Regression shrinkage and selection via the lasso. Journal of the Royal Statistical Society. Series B (Methodological), 58(1), 267–288.
- Zhang, C.-H. (2010). Nearly unbiased variable selection under minimax concave penalty. The Annals of Statistics, 38(2), 894–942. https://doi.org/10.1214/09-AOS729
- Zhang, T. (2010). Analysis of Multi-stage Convex Relaxation for Sparse Regularization. Journal of Machine Learning Research, 11, 1081–1107.
- Zou, H. (2006). The adaptive lasso and its oracle properties. Journal of the American Statistical Association, 101(476), 1418–1429. https://doi.org/10.1198/016214506000000735
- Zou, H., & Hastie, T. (2005). Regularization and variable selection via the elastic net. Journal of the Royal Statistical Society: Series B, 67(2), 301–320. https://doi.org/10.1111/j.1467-9868.2005.00503.x
- Friedman, J., Hastie, T., & Tibshirani, R. (2010). Regularization paths for generalized linear models via coordinate descent. Journal of Statistical Software, 33(1), 1–20. https://doi.org/10.18637/jss.v033.i01
- Yuan, G.-X., Ho, C.-H., & Lin, C.-J. (2012). An improved GLMNET for l1-regularized logistic regression. The Journal of Machine Learning Research, 13, 1999–2030. https://doi.org/10.1145/2020408.2020421
- Beck, A., & Teboulle, M. (2009). A Fast Iterative Shrinkage-Thresholding Algorithm for Linear Inverse Problems. SIAM Journal on Imaging Sciences, 2(1), 183–202. https://doi.org/10.1137/080716542
- Gong, P., Zhang, C., Lu, Z., Huang, J., & Ye, J. (2013). A general iterative shrinkage and thresholding algorithm for non-convex regularized optimization problems. Proceedings of the 30th International Conference on Machine Learning, 28(2)(2), 37–45.
- Parikh, N., & Boyd, S. (2013). Proximal Algorithms. Foundations and Trends in Optimization, 1(3), 123–231.
- Liang, X., Yang, Y., & Huang, J. (2018). Evaluation of structural relationships in autoregressive cross-lagged models under longitudinal approximate invariance: A Bayesian analysis. Structural Equation Modeling: A Multidisciplinary Journal, 25(4), 558–572. https://doi.org/10.1080/10705511.2017.1410706
- Bauer, D. J., Belzak, W. C. M., & Cole, V. T. (2020). Simplifying the Assessment of Measurement Invariance over Multiple Background Variables: Using Regularized Moderated Nonlinear Factor Analysis to Detect Differential Item Functioning. Structural Equation Modeling: A Multidisciplinary Journal, 27(1), 43–55. https://doi.org/10.1080/10705511.2019.1642754
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