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Abstract

When item scores are ordered categorical, categorical omega can be computed based on the parameter estimates from a factor analysis model using frequentist estimators such as diagonally weighted least squares. When the sample size is relatively small and thresholds are different across items, using diagonally weighted least squares can yield a substantially biased estimate of categorical omega. In this study, we applied Bayesian estimation methods for computing categorical omega. The simulation study investigated the performance of categorical omega under a variety of conditions through manipulating the scale length, number of response categories, distributions of the categorical variable, heterogeneities of thresholds across items, and prior distributions for model parameters. The Bayes estimator appears to be a promising method for estimating categorical omega. Mplus and SAS codes for computing categorical omega were provided.

Keywords

categorical omega Bayesian estimation factor analysis small sample size prior specification

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References

Arminger

Muthén

B. O.

(1998). A Bayesian approach to nonlinear latent variable models using the Gibbs sampler and the Metropolis-Hastings algorithm. Psychometrika, 63, 271-300.

Asparouhov

Muthén

B. O.

(2010). Bayesian analysis using Mplus: Technical implementation. Retrieved from https://www.statmodel.com/download/Bayes3.pdf

Bentler

P. M.

(1985-2017). EQS 6.3 for Windows. Los Angeles, CA: Multivariate Software.

Bentler

P. M.

(2009). Alpha, dimension-free, and model-based internal consistency reliability. Psychometrika, 74, 137-143.

Bollen

K. A.

(1989). Structural equation modeling with latent variables. New York, NY: Wiley.

Crocker

Algina

(1986). Introduction to classical & modern test theory. Belmont, CA: Wadsworth Group/Thomson Learning.

DiStefano

Morgan

G. B.

(2014). A comparison of diagonal weighted least squares robust estimation techniques for ordinal data. Structural Equation Modeling, 21, 425-438.

Finney

DiStefano

(2013). Non-normal and categorical data in structural equation modeling. In Hancock

G. R.

Mueller

R. O.

(Eds.), Structural equation modeling: A second course (2nd ed., pp. 439-492). Greenwich, CT: Information Age.

Garrido

L. E.

Abad

F. J.

Ponsoda

(2016). Are fit indices really fit to estimate the number of factors with categorical variables? Some cautionary findings via Monte Carlo simulation. Psychological Methods, 21(1), 93-111.

10.

Geman

(1984). Stochastic relaxation, Gibbs distributions, and the Bayesian restoration of images. IEE Transactions on Pattern Analysis and Machine Intelligence, PAMI-6, 721-741.

11.

Gilks

W. R.

Richardson

Spiegelhalter

D. J.

(Eds.). (1996). Markov chain Monte Carlo in practice. London, England: Chapman & Hall.

12.

Green

S. B.

Yang

(2009). Reliability of summed item scores using structural equation modeling: An alternative to coefficient alpha. Psychometrika, 74, 155-167.

13.

Heise

D. R.

Bohrnstedt

G. W.

(1970). Validity, invalidity, and reliability. Sociological Methodology, 2, 104-129.

14.

Holtmann

Koch

Lochner

Eid

(2016). A comparison of ML, WLSMV, and Bayesian methods for multilevel structural equation models in small samples: A simulation study. Multivariate Behavioral Research, 51, 661-680.

15.

Kelley

Pornprasertmanit

(2016). Confidence intervals for population reliability coefficients: Evaluation of methods, recommendations, and software for composite measures. Psychological Methods, 21, 69-92.

16.

Lee

S. Y.

(2007). Structural equation modeling: A Bayesian approach (Vol. 711). New York, NY: John Wiley.

17.

Liang

Yang

(2014). An evaluation of WLSMV and Bayesian methods for confirmatory factor analysis with categorical indicators. International Journal of Quantitative Research in Education, 2(1), 17-38.

18.

Lord

F. M.

Novick

M. R.

(1968). Statistical theory of mental test scores. Reading, MA: Addison-Wesley.

19.

McDonald

R. P.

(1999). Test theory: A unified approach. Hillsdale, NJ: Erlbaum.

20.

Muthén

B. O.

(1978). Contributions to factor analysis of dichotomous variables. Psychometrika, 43, 551-560.

21.

Muthén

B. O.

Asparouhov

(2012). Bayesian structural equation modeling: A more flexible representation of substantive theory. Psychological Methods, 17, 313-335.

22.

Muthén

L. K.

Muthén

B. O.

(1998-2015). Mplus user’s guide (7th ed.). Los Angeles, CA: Muthén & Muthén.

23.

Nguyen

T. Q.

Webb-Vargas

Koning

I. M.

Stuart

E. A.

(2016). Causal mediation analysis with a binary outcome and multiple continuous or ordinal mediators: Simulations and application to an alcohol intervention. Structural Equation Modeling, 23, 368-383.

24.

Olsson

(1979). Maximum likelihood estimation of the polychoric correlation coefficient. Psychometrika, 44, 443-460.

25.

Raykov

Marcoulides

G. A.

(2015). On the relationship between classical test theory and item response theory: From one to the other and back. Educational and Psychological Measurement, 76, 325-338.

26.

Raykov

Shrout

P. E.

(2002). Reliability of scales with general structure: Point and interval estimation using a structural equation modeling approach. Structural Equation Modeling, 9, 195-212.

27.

Reise

S. P.

Scheines

Widaman

K. F.

Haviland

M. G.

(2013). Multidimensionality and structural coefficient bias in structural equation modeling: A bifactor perspective. Educational and Psychological Measurement, 73, 5-26.

28.

Rhemtulla

Brosseau-Liard

P. E.

Savalei

(2012). When can categorical variables be treated as continuous? A comparison of robust continuous and categorical SEM estimation methods under suboptimal conditions. Psychological Methods, 17, 354-373.

29.

Rosseel

(2012). lavaan: An R package for structural equation modeling. Journal of Statistical Software, 48(2), 1-36.

30.

Savalei

(2011). What to do about zero frequency cells when estimating polychoric correlations. Structural Equation Modeling, 18, 253-273.

31.

Savalei

Rhemtulla

(2013). The performance of robust test statistics with categorical data. British Journal of Mathematical and Statistical Psychology, 66, 201-223.

32.

Yang

Green

S. B.

(2015). Evaluation of structural equation modeling estimates of reliability for scales with ordered categorical items. Methodology: European Journal of Research Methods for the Behavioral and Social Sciences, 11(1), 23-34.

33.

Yang

Xia

(2015). On the number of factors to retain in exploratory factor analysis for ordered categorical data. Behavioral Research Methods, 47, 756-772.

34.

Yang-Wallentin

Jöreskog

K. G.

Luo

(2010). Confirmatory factor analysis of ordinal variables with misspecified models. Structural Equation Modeling, 17, 392-423.

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Categorical Omega With Small Sample Sizes via Bayesian Estimation: An Alternative to Frequentist Estimators

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