README

MIRES

MIRES is a package for Measurement Invariance assessment using Random Effects and Shrinkage. This is the official implementation of the approach taken in Measurement Invariance Assessment with Bayesian Hierarchical Inclusion Modeling.

Unlike most other MI assessment methods, MIRES assumes all measurement parameters (loadings, intercepts, and residual SDs) can randomly vary across groups. Therefore, it is a fully mixed effects CFA model. If invariance is tenable, then the random effect SDs should all be effectively zero.

Unlike most mixed effects models, MIRES further regularizes the random effect SDs (RE-SDs) via an inclusion model. In sum, it includes an adaptive, dependent regularization model that shares regularization intensity across several RE-SDs. This allows the RE-SDs to rapidly shrink toward zero if they need to (i.e., if invariance is met), and to be largely untouched if they need to be non-zero (i.e., if invariance is not met). Consequently, MIRES can gain evidence in favor of invariance quicker than a mixed effects model otherwise could, especially with few groups.

Altogether, MIRES is a mixed effects CFA model, where the RE-SDs are also hierarchically modeled with a dependent regularizing prior (See Details for more information). When invariance is plausible, it will collapse into a fixed effects CFA model; when it is not, then a partially invariant or fully non-invariant model will be produced.

Installation

remotes::install_github("stephenSRMMartin/MIRES")

Example

library(MIRES)
data(sim_loadings)
head(sim_loadings)

x_1 x_2 x_3 x_4 x_5 x_6 1 1.7400023 1.3214588 0.6255326 0.901031733 0.9495002 1.2286485 2 -0.5640201 0.2203121 -1.4399299 -0.571124405 -0.9580103 -0.2434576 3 -1.1030768 -0.4088069 0.7182129 -0.009960373 -1.3954430 -0.1966013 4 -1.6139970 -1.3411869 -2.7745400 -0.818880762 -2.1656676 -1.1999327 5 -0.8192840 -0.9715812 -0.3293007 -0.538967762 -0.7168703 -0.4190734 6 0.3266671 0.8955085 2.4646536 0.596746521 1.5468213 0.4509530 x_7 x_8 group 1 0.3128417 1.5761853 1 2 -1.1585096 -1.1884185 1 3 -0.6639108 -0.6313458 1 4 -1.4482666 -2.3015851 1 5 -2.7528062 -1.0865613 1 6 3.1724797 2.1475378 1

fit <- mires(my_factor ~ x_1 + x_2 + x_3 + x_4 + x_5 + x_6 + x_7 + x_8, group, sim_loadings, iter = 1000)
summary(fit)

----- MIRES model object ----- Specification: my_factor ~ x_1 + x_2 + x_3 + x_4 + x_5 + x_6 + x_7 + x_8 ----- Configuration: Factors: Univariate Latent Mean and Variance Identification: Sum-to-zero, product-to-one. Hierarchical inclusion model: Yes Latent Scores Saved: No Inclusion Model Prior Params: 0 , 0.25 ----- Fixed Effects ----- Loadings Item Mean Median SD L95 U95 Rhat x_1 0.757 0.750 0.139 0.502 1.045 1.001 x_2 0.668 0.656 0.221 0.276 1.154 1.001 x_3 0.750 0.739 0.143 0.487 1.070 1.000 x_4 0.579 0.573 0.204 0.193 1.001 1.007 x_5 0.707 0.693 0.232 0.292 1.215 1.003 x_6 0.791 0.786 0.229 0.288 1.218 1.005 x_7 0.594 0.580 0.229 0.159 1.056 1.003 x_8 1.009 1.003 0.211 0.587 1.429 1.002 Residual Standard Deviations (Unlogged Scale) Item Mean Median SD L95 U95 Rhat x_1 0.754 0.750 0.061 0.652 0.891 1.001 x_2 0.743 0.740 0.052 0.633 0.839 1.001 x_3 0.750 0.747 0.051 0.653 0.854 1.004 x_4 0.695 0.692 0.051 0.596 0.791 1.001 x_5 0.687 0.685 0.051 0.590 0.788 1.001 x_6 0.710 0.709 0.057 0.594 0.819 1.002 x_7 0.720 0.715 0.051 0.624 0.819 1.005 x_8 0.788 0.785 0.064 0.679 0.932 1.001 Intercepts Item Mean Median SD L95 U95 Rhat x_1 -0.040 -0.040 0.083 -0.201 0.121 1.002 x_2 -0.029 -0.028 0.078 -0.190 0.114 1.003 x_3 -0.033 -0.035 0.086 -0.198 0.134 1.002 x_4 0.008 0.008 0.067 -0.112 0.152 1.001 x_5 -0.107 -0.107 0.079 -0.252 0.057 1.002 x_6 -0.014 -0.008 0.098 -0.222 0.160 1.005 x_7 -0.038 -0.037 0.091 -0.219 0.136 1.003 x_8 -0.025 -0.027 0.092 -0.202 0.156 1.002 ----- Measurement Invariance Assessment ----- Random Effect Standard Deviations (Unlogged Scale) Parameter Item Factor Mean Median SD L95 U95 Rhat BF01 BF10 Pr(SD <= 0.1| D) BF(SD <= 0.1) Loading x_1 my_factor 0.219 0.192 0.156 0.000 0.504 1.008 2.107 0.475 0.232 3.046 Loading x_2 my_factor 0.437 0.401 0.181 0.182 0.768 1.002 0.001 729.233 0.000 0.000 Loading x_3 my_factor 0.225 0.192 0.162 0.000 0.523 1.003 1.933 0.517 0.216 2.777 Loading x_4 my_factor 0.388 0.352 0.180 0.104 0.767 1.002 0.017 58.707 0.007 0.071 Loading x_5 my_factor 0.460 0.425 0.191 0.161 0.836 1.002 0.004 244.913 0.001 0.010 Loading x_6 my_factor 0.473 0.429 0.207 0.146 0.903 1.003 0.023 42.880 0.002 0.025 Loading x_7 my_factor 0.467 0.430 0.185 0.173 0.827 1.001 0.002 480.630 0.000 0.000 Loading x_8 my_factor 0.407 0.375 0.193 0.076 0.798 1.003 0.131 7.628 0.021 0.222 Residual SD x_1 0.114 0.093 0.095 0.000 0.289 1.003 6.617 0.151 0.529 11.355 Residual SD x_2 0.092 0.073 0.076 0.000 0.236 1.001 7.097 0.141 0.641 18.052 Residual SD x_3 0.079 0.063 0.068 0.000 0.209 1.005 8.589 0.116 0.712 24.934 Residual SD x_4 0.083 0.067 0.074 0.000 0.218 0.999 9.658 0.104 0.697 23.202 Residual SD x_5 0.090 0.071 0.077 0.000 0.236 1.003 8.955 0.112 0.650 18.776 Residual SD x_6 0.100 0.077 0.089 0.000 0.264 1.000 6.815 0.147 0.617 16.287 Residual SD x_7 0.087 0.068 0.078 0.000 0.235 1.005 357.644 0.003 0.676 21.094 Residual SD x_8 0.084 0.066 0.076 0.000 0.225 1.002 9.266 0.108 0.688 22.294 Intercept x_1 0.094 0.072 0.089 0.000 0.258 1.001 8.213 0.122 0.647 18.571 Intercept x_2 0.091 0.074 0.077 0.000 0.238 1.003 8.168 0.122 0.636 17.703 Intercept x_3 0.096 0.077 0.079 0.000 0.245 1.003 6.632 0.151 0.622 16.601 Intercept x_4 0.065 0.050 0.061 0.000 0.173 0.999 13.225 0.076 0.803 41.211 Intercept x_5 0.092 0.074 0.078 0.000 0.233 1.004 7.707 0.130 0.644 18.329 Intercept x_6 0.126 0.104 0.100 0.000 0.316 1.001 5.705 0.175 0.482 9.426 Intercept x_7 0.139 0.121 0.100 0.000 0.328 1.001 2.978 0.336 0.396 6.629 Intercept x_8 0.093 0.072 0.085 0.000 0.251 1.001 173.931 0.006 0.642 18.131

Limitations

Details

With three kinds of parameters (loadings, residual SDs, and intercepts), and J items, there are 3J RE-SDs: \(\sigma_p, p \in [0,\ldots,3J]\). The regularizing prior for each RE-SD, \(\sigma_p\) is defined as: \[ \sigma_p \sim \mathcal{N}^+(0, \exp(\tau_p)) \] If \(\exp(\tau_p)\) is very small, then the prior probability that \(\sigma_p = 0\) increases greatly, and the parameter corresponding to it is reduced to a fixed effect.

The probability that one parameter is invariant should be informed by other parameters with similar characteristics (e.g., they model the same item, or they are of the same type — Loading, intercept, or residual SD). Therefore, the regularization term for each \(\sigma_p\) can be dependent on others. We model the regularization terms \(\tau_p\) as: \[ \tau_p = \tau_0 + \tau_{\text{item}_p} + \tau_{\text{param}_p} + \lambda_p \] Therefore, there is a global scaling factor \(\tau_0\), an “item” effect (\(\tau_{\text{item}, p}), a "parameter" effect (\)_{, p}), and a unique effect \(\lambda_p\).

Therefore, if all parameters are invariant, \(\tau_0\) can decrease, and all RE-SDs can jointly approach zero. Conversely, if some loadings are invariant, then \(\tau_{\lambda}\) decreases, and the probability that other loadings are zero increases. If item \(j\)’s intercept and loading seems to vary, then \(\tau_j\) increases, and the probability that the item’s residual SD is invariant decreases. Finally, the \(\lambda_p\) terms provide an “escape hatch” of sorts, if a particular parameter uniquely needs to be invariant or non-invariant.