Nothing
Penalized Factor Analysis: grid search"
In penfa: Single- And Multiple-Group Penalized Factor Analysis
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Introduction
Aim. This vignette shows how to fit a penalized factor analysis model with
the scad and mcp penalties using the routines in the penfa package. The
employed penalty is aimed at encouraging sparsity in the factor loading matrix.
Since the scad and mcp penalties cannot be used with the automatic tuning
procedure (see Geminiani et al., 2021 for details), the optimal tuning parameter
will be found through grid searches.
Data. For illustration purposes, we use the cross-cultural data set ccdata
containing the standardized ratings to 12 items concerning organizational
citizenship behavior. Employees from different countries were asked to rate
their attitudes towards helping other employees and giving suggestions for
improved work conditions. The items are thought to measure two latent factors:
help, defined by the first seven items (h1 to h7), and voice,
represented by the last five items (v1 to v5). See ?ccdata for details.
This data set is a standardized version of the one in the
ccpsyc package, and only considers
employees from Lebanon and Taiwan (i.e., "LEB", "TAIW").
This vignette is meant as a demo of the capabilities of penfa; please refer to
Fischer et al. (2019) and Fischer and Karl (2019) for a description and
analysis of these data.
Let us load and inspect ccdata.
library(penfa)
data(ccdata)
summary(ccdata)
Model specification
Before fitting the model, we need to write a model syntax describing the
relationships between the items and the latent factors. To facilitate its
formulation, the rules for the syntax specification broadly follow the ones
required by lavaan. The
syntax must be enclosed in single quotes ' '.
syntax = 'help =~ h1 + h2 + h3 + h4 + h5 + h6 + h7 + 0*v1 + v2 + v3 + v4 + v5
voice =~ 0*h1 + h2 + h3 + h4 + h5 + h6 + h7 + v1 + v2 + v3 + v4 + v5'
The factors help and voice appear on the left-hand side, whereas the
observed variables on the left-hand side. Following the rationale in Geminiani
et al. (2021), we only specify the minimum number of identification constraints.
We are setting the scales of the factors by fixing their factor variances to 1.
This can be done in one of two ways: 1) by adding 'help ~~ 1*help' and 'voice
~~ 1*voice' to the syntax above; or 2) by setting the argument std.lv = TRUE
in the fitting function (see below). To avoid rotational freedom, we fix one
loading per factor to zero. Parameters can be easily fixed to user-defined
values through the pre-multiplication mechanism. By default, unique variances
are automatically added to the model, and the factors are allowed to correlate.
These specifications can be modified by altering the syntax (see ?penfa for
details on how to write the model syntax).
Model fitting
The core of the package is given by the penfa function, a short form for
PENalized Factor Analysis, that implements the framework discussed in
Geminiani et al. (2021). If users decide for either the
scad or mcp penalties, they need to use strategy = "fixed" since the
automatic procedure is not feasible.
Scad
We start off with the scad. In the function call, we now specify pen.shrink =
"scad", and we provide through the eta argument the fixed value of the tuning
parameter to be employed during optimization (here, for instance, 0.05). The
name given to the starting value (here, the factor loading matrix "lambda")
reflects the parameter matrix to be penalized. All of its elements are
penalized, which means here that the penalization is applied to all factor
loadings (except the ones fixed for identification). The scad penalty relies on
an additional shape parameter, which is set by default to 3.7 (Fan and Li
2001). This value can be conveniently modified through the a.scad argument.
See ?penfaOptions for additional details on the possible options.
scad.fit <- penfa(## factor model
model = syntax,
data = ccdata,
std.lv = TRUE,
## penalization
pen.shrink = "scad",
eta = list(shrink = c("lambda" = 0.05), diff = c("none" = 0)),
## fixed tuning
strategy = "fixed")
Grid search
In order to find the optimal value of the tuning parameter, a grid search needs
to be conducted, and the optimal model is the one with the lowest GBIC
(Generalized Bayesian Information Criterion). For demo purposes, we use a grid
of 51 values evenly spaced between 0 and 0.15. However, for accurate analyses,
please consider finer grids (of at least 200 elements) with an upper bound
reasonable for the data at hand.
# Grid of values for tuning parameter
eta.grid <- seq(0, 0.15, length.out = 51)
# Return GBIC from a converged and admissible penfa model with fixed tuning
penfa.fixedTun <- function(eta, penalty, ...){
fitted <- penfa(model = syntax, data = ccdata,
std.lv = TRUE, pen.shrink = penalty,
eta = list(shrink = c("lambda" = eta), diff = c("none" = 0)),
strategy = "fixed", verbose = FALSE, ...)
if(all(fitted@Vcov$solution) & fitted@Vcov$admissibility)
return(BIC(fitted))
}
# additional penfaOptions can be passed
GBIC.scad <- sapply(eta.grid, penfa.fixedTun, penalty = "scad")
The optimal tuning parameter is the one generating the penalized model with the
lowest GBIC.
optimtun.scad <- eta.grid[[which.min(GBIC.scad)]]
# To plot GBIC across tuning values
# p <- plotly::plot_ly(x = eta.grid, y = GBIC.scad, type = 'scatter', mode = 'lines')
# plotly::layout(p, xaxis = list(showline = TRUE),
# title = list(text = "GBIC values across tuning parameters"))
We can ultimately fit the model with the optimal tuning parameter (here, r optimtun.scad).
The summary method details information on the model characteristics, the
optimization and penalization procedures as well as the parameter estimates with
associated standard errors and confidence intervals. The Type column
distinguishes between the fixed parameters set to specific values for
identification, the free parameters that have been estimated through ordinary
maximum likelihood, and the penalized (pen) parameters. The standard errors
here have been computed as the square root of the inverse of the penalized
Fisher information matrix (Geminiani et al., 2021). The last columns report 95%
confidence intervals (CI) for the model parameters. Standard errors and CI of
the penalized parameters shrunken to zero are not displayed. A different
significance level can be specified through the level argument in the
summary call.
scad.fit <- penfa(## factor model
model = syntax,
data = ccdata,
std.lv = TRUE,
## penalization
pen.shrink = "scad",
# optimal tuning
eta = list(shrink = c("lambda" = optimtun.scad), diff = c("none" = 0)),
strategy = "fixed",
verbose = FALSE)
summary(scad.fit)
The penalty matrix can be inspected and plotted as shown in
"plotting-penalty-matrix".
Implied moments
The implied moments (here, the covariance matrix) can be found via the fitted
method.
implied <- fitted(scad.fit)
implied
Factor scores
Lastly, the factor scores can be calculated via the penfaPredict function.
fscores <- penfaPredict(scad.fit)
head(fscores)
Mcp
We can fit a penalized factor model with the mcp penalty in a way similar to the
scad. By default the shape parameter of the mcp is set to 3. This value can be
conveniently modified through the a.mcp argument. See ?penfaOptions for
additional details on the possible options.
GBIC.mcp <- sapply(eta.grid, penfa.fixedTun, penalty = "mcp")
optimtun.mcp <- eta.grid[[which.min(GBIC.mcp)]]
optimtun.mcp
The tuning value equal to r optimtun.mcp generated the model with the lowest GBIC.
mcp.fit <- penfa(## factor model
model = syntax,
data = ccdata,
std.lv = TRUE,
## penalization
pen.shrink = "mcp",
# optimal tuning
eta = list(shrink = c("lambda" = optimtun.mcp), diff = c("none" = 0)),
strategy = "fixed",
verbose = FALSE)
summary(mcp.fit)
Conclusion
Implementing the above approach in the multiple-group case would imply carrying
out grid searches in three dimensions to find the optimal tuning parameter
vector. This is clearly not advisable, as it would introduce further
complications and possibly new computational problems and instabilities. For
this reason, we suggest users to rely on the automatic tuning parameter
selection procedure, whose applicability is demonstrated in the
vignettes for single (vignette("automatic-tuning-selection")) and
multiple-group ("multiple-group-analysis") penalized models.
R Session
sessionInfo()
References
-
Fan, J., & Li, R. 2001. "Variable Selection via Nonconcave Penalized Likelihood
and Its Oracle Properties." Journal of the American Statistical
Association 96(456), 1348–60. https://doi.org/10.1198/016214501753382273
-
Fischer, R., Ferreira, M. C., Van Meurs, N. et al. (2019). "Does
Organizational Formalization Facilitate Voice and Helping Organizational
Citizenship Behaviors? It Depends on (National) Uncertainty Norms." Journal of
International Business Studies, 50(1), 125-134.
https://doi.org/10.1057/s41267-017-0132-6
-
Fischer, R., & Karl, J. A. (2019). "A Primer to (Cross-Cultural) Multi-Group
Invariance Testing Possibilities in R." Frontiers in psychology, 10, 1507. https://doi.org/10.3389/fpsyg.2019.01507
-
Geminiani, E. (2020). "A Penalized Likelihood-Based Framework for Single and
Multiple-Group Factor Analysis Models." PhD thesis, University of Bologna.
http://amsdottorato.unibo.it/9355/
-
Geminiani, E., Marra, G., & Moustaki, I. (2021). "Single- and Multiple-Group
Penalized Factor Analysis: A Trust-Region Algorithm Approach with Integrated
Automatic Multiple Tuning Parameter Selection." Psychometrika, 86(1), 65-95. https://doi.org/10.1007/s11336-021-09751-8
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penfa documentation built on July 17, 2021, 9:08 a.m.
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```{css, echo=FALSE} pre { max-height: 600px; overflow-y: auto; }
pre[class] { max-height: 600px; }
```r knitr::opts_chunk$set(collapse = TRUE)
Introduction
Aim. This vignette shows how to fit a penalized factor analysis model with
the scad and mcp penalties using the routines in the penfa package. The
employed penalty is aimed at encouraging sparsity in the factor loading matrix.
Since the scad and mcp penalties cannot be used with the automatic tuning
procedure (see Geminiani et al., 2021 for details), the optimal tuning parameter
will be found through grid searches.
Data. For illustration purposes, we use the cross-cultural data set ccdata
containing the standardized ratings to 12 items concerning organizational
citizenship behavior. Employees from different countries were asked to rate
their attitudes towards helping other employees and giving suggestions for
improved work conditions. The items are thought to measure two latent factors:
help, defined by the first seven items (h1 to h7), and voice,
represented by the last five items (v1 to v5). See ?ccdata for details.
This data set is a standardized version of the one in the
ccpsyc package, and only considers
employees from Lebanon and Taiwan (i.e., "LEB", "TAIW").
This vignette is meant as a demo of the capabilities of penfa; please refer to
Fischer et al. (2019) and Fischer and Karl (2019) for a description and
analysis of these data.
Let us load and inspect ccdata.
library(penfa) data(ccdata) summary(ccdata)
Model specification
Before fitting the model, we need to write a model syntax describing the
relationships between the items and the latent factors. To facilitate its
formulation, the rules for the syntax specification broadly follow the ones
required by lavaan. The
syntax must be enclosed in single quotes ' '.
syntax = 'help =~ h1 + h2 + h3 + h4 + h5 + h6 + h7 + 0*v1 + v2 + v3 + v4 + v5 voice =~ 0*h1 + h2 + h3 + h4 + h5 + h6 + h7 + v1 + v2 + v3 + v4 + v5'
The factors help and voice appear on the left-hand side, whereas the
observed variables on the left-hand side. Following the rationale in Geminiani
et al. (2021), we only specify the minimum number of identification constraints.
We are setting the scales of the factors by fixing their factor variances to 1.
This can be done in one of two ways: 1) by adding 'help ~~ 1*help' and 'voice
~~ 1*voice' to the syntax above; or 2) by setting the argument std.lv = TRUE
in the fitting function (see below). To avoid rotational freedom, we fix one
loading per factor to zero. Parameters can be easily fixed to user-defined
values through the pre-multiplication mechanism. By default, unique variances
are automatically added to the model, and the factors are allowed to correlate.
These specifications can be modified by altering the syntax (see ?penfa for
details on how to write the model syntax).
Model fitting
The core of the package is given by the penfa function, a short form for
PENalized Factor Analysis, that implements the framework discussed in
Geminiani et al. (2021). If users decide for either the
scad or mcp penalties, they need to use strategy = "fixed" since the
automatic procedure is not feasible.
Scad
We start off with the scad. In the function call, we now specify pen.shrink =
"scad", and we provide through the eta argument the fixed value of the tuning
parameter to be employed during optimization (here, for instance, 0.05). The
name given to the starting value (here, the factor loading matrix "lambda")
reflects the parameter matrix to be penalized. All of its elements are
penalized, which means here that the penalization is applied to all factor
loadings (except the ones fixed for identification). The scad penalty relies on
an additional shape parameter, which is set by default to 3.7 (Fan and Li
2001). This value can be conveniently modified through the a.scad argument.
See ?penfaOptions for additional details on the possible options.
scad.fit <- penfa(## factor model model = syntax, data = ccdata, std.lv = TRUE, ## penalization pen.shrink = "scad", eta = list(shrink = c("lambda" = 0.05), diff = c("none" = 0)), ## fixed tuning strategy = "fixed")
Grid search
In order to find the optimal value of the tuning parameter, a grid search needs to be conducted, and the optimal model is the one with the lowest GBIC (Generalized Bayesian Information Criterion). For demo purposes, we use a grid of 51 values evenly spaced between 0 and 0.15. However, for accurate analyses, please consider finer grids (of at least 200 elements) with an upper bound reasonable for the data at hand.
# Grid of values for tuning parameter eta.grid <- seq(0, 0.15, length.out = 51) # Return GBIC from a converged and admissible penfa model with fixed tuning penfa.fixedTun <- function(eta, penalty, ...){ fitted <- penfa(model = syntax, data = ccdata, std.lv = TRUE, pen.shrink = penalty, eta = list(shrink = c("lambda" = eta), diff = c("none" = 0)), strategy = "fixed", verbose = FALSE, ...) if(all(fitted@Vcov$solution) & fitted@Vcov$admissibility) return(BIC(fitted)) } # additional penfaOptions can be passed GBIC.scad <- sapply(eta.grid, penfa.fixedTun, penalty = "scad")
The optimal tuning parameter is the one generating the penalized model with the
lowest GBIC.
optimtun.scad <- eta.grid[[which.min(GBIC.scad)]] # To plot GBIC across tuning values # p <- plotly::plot_ly(x = eta.grid, y = GBIC.scad, type = 'scatter', mode = 'lines') # plotly::layout(p, xaxis = list(showline = TRUE), # title = list(text = "GBIC values across tuning parameters"))
We can ultimately fit the model with the optimal tuning parameter (here, r optimtun.scad).
The summary method details information on the model characteristics, the
optimization and penalization procedures as well as the parameter estimates with
associated standard errors and confidence intervals. The Type column
distinguishes between the fixed parameters set to specific values for
identification, the free parameters that have been estimated through ordinary
maximum likelihood, and the penalized (pen) parameters. The standard errors
here have been computed as the square root of the inverse of the penalized
Fisher information matrix (Geminiani et al., 2021). The last columns report 95%
confidence intervals (CI) for the model parameters. Standard errors and CI of
the penalized parameters shrunken to zero are not displayed. A different
significance level can be specified through the level argument in the
summary call.
scad.fit <- penfa(## factor model model = syntax, data = ccdata, std.lv = TRUE, ## penalization pen.shrink = "scad", # optimal tuning eta = list(shrink = c("lambda" = optimtun.scad), diff = c("none" = 0)), strategy = "fixed", verbose = FALSE) summary(scad.fit)
The penalty matrix can be inspected and plotted as shown in "plotting-penalty-matrix".
Implied moments
The implied moments (here, the covariance matrix) can be found via the fitted
method.
implied <- fitted(scad.fit) implied
Factor scores
Lastly, the factor scores can be calculated via the penfaPredict function.
fscores <- penfaPredict(scad.fit) head(fscores)
Mcp
We can fit a penalized factor model with the mcp penalty in a way similar to the
scad. By default the shape parameter of the mcp is set to 3. This value can be
conveniently modified through the a.mcp argument. See ?penfaOptions for
additional details on the possible options.
GBIC.mcp <- sapply(eta.grid, penfa.fixedTun, penalty = "mcp") optimtun.mcp <- eta.grid[[which.min(GBIC.mcp)]] optimtun.mcp
The tuning value equal to r optimtun.mcp generated the model with the lowest GBIC.
mcp.fit <- penfa(## factor model model = syntax, data = ccdata, std.lv = TRUE, ## penalization pen.shrink = "mcp", # optimal tuning eta = list(shrink = c("lambda" = optimtun.mcp), diff = c("none" = 0)), strategy = "fixed", verbose = FALSE) summary(mcp.fit)
Conclusion
Implementing the above approach in the multiple-group case would imply carrying
out grid searches in three dimensions to find the optimal tuning parameter
vector. This is clearly not advisable, as it would introduce further
complications and possibly new computational problems and instabilities. For
this reason, we suggest users to rely on the automatic tuning parameter
selection procedure, whose applicability is demonstrated in the
vignettes for single (vignette("automatic-tuning-selection")) and
multiple-group ("multiple-group-analysis") penalized models.
R Session
sessionInfo()
References
-
Fan, J., & Li, R. 2001. "Variable Selection via Nonconcave Penalized Likelihood and Its Oracle Properties." Journal of the American Statistical Association 96(456), 1348–60. https://doi.org/10.1198/016214501753382273
-
Fischer, R., Ferreira, M. C., Van Meurs, N. et al. (2019). "Does Organizational Formalization Facilitate Voice and Helping Organizational Citizenship Behaviors? It Depends on (National) Uncertainty Norms." Journal of International Business Studies, 50(1), 125-134. https://doi.org/10.1057/s41267-017-0132-6
-
Fischer, R., & Karl, J. A. (2019). "A Primer to (Cross-Cultural) Multi-Group Invariance Testing Possibilities in R." Frontiers in psychology, 10, 1507. https://doi.org/10.3389/fpsyg.2019.01507
-
Geminiani, E. (2020). "A Penalized Likelihood-Based Framework for Single and Multiple-Group Factor Analysis Models." PhD thesis, University of Bologna. http://amsdottorato.unibo.it/9355/
-
Geminiani, E., Marra, G., & Moustaki, I. (2021). "Single- and Multiple-Group Penalized Factor Analysis: A Trust-Region Algorithm Approach with Integrated Automatic Multiple Tuning Parameter Selection." Psychometrika, 86(1), 65-95. https://doi.org/10.1007/s11336-021-09751-8
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