Hostname: page-component-6bf8c574d5-gr6zb Total loading time: 0 Render date: 2025-02-22T04:45:18.971Z Has data issue: false hasContentIssue false
  • English
  • Français

Higher-Order Latent Trait Models for Cognitive Diagnosis

Published online by Cambridge University Press:  01 January 2025

Jimmy de la Torre  and
Jeffrey A. Douglas
Jimmy de la Torre*
Affiliation:
Rutgers, The State University of New Jersey
Jeffrey A. Douglas
Affiliation:
University of Illinois
*
Correspondence should be sent to Jimmy de la Torre, Department of Educational Psychology, Rutgers, The State University of New Jersey, 10 Seminary Place, New Brunswick, NJ 08901, USA. E-Mail: [email protected]
Get access Rights & Permissions [Opens in a new window]

Abstract

Higher-order latent traits are proposed for specifying the joint distribution of binary attributes in models for cognitive diagnosis. This approach results in a parsimonious model for the joint distribution of a high-dimensional attribute vector that is natural in many situations when specific cognitive information is sought but a less informative item response model would be a reasonable alternative. This approach stems from viewing the attributes as the specific knowledge required for examination performance, and modeling these attributes as arising from a broadly-defined latent trait resembling the ϑ of item response models. In this way a relatively simple model for the joint distribution of the attributes results, which is based on a plausible model for the relationship between general aptitude and specific knowledge. Markov chain Monte Carlo algorithms for parameter estimation are given for selected response distributions, and simulation results are presented to examine the performance of the algorithm as well as the sensitivity of classification to model misspecification. An analysis of fraction subtraction data is provided as an example.

Keywords

cognitive diagnosisitem response theorylatent class modelMarkov chain Monte Carlo
Type
Theory and Methods
Information
Psychometrika , Volume 69 , Issue 3 , September 2004 , pp. 333 - 353
Copyright
Copyright © 2004 The Psychometric Society

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

Footnotes

This research was funded by National Institute of Health grant R01 CA81068. We would like to thank William Stout and Sarah Hartz for many useful discussions, three anonymous reviewers for helpful comments and suggestions, and Kikumi Tatsuoka and Curtis Tatsuoka for generously sharing data.

References

Best, N.G., Cowles, M.K., & Vines, S.K. (1995). CODA: Convergence diagnosis and output analysis software for Gibbs sampling output (Version 0.30). [Computer software]. Cambridge: MRC Biostatistics UnitGoogle Scholar
Bock, R.D., & Aitken, M. (1981). Marginal maximum likelihood estimation of item parameters: Application of an EM algorithm. Psychometrika, 46, 443459CrossRefGoogle Scholar
Casella, G., & George, E.I. (1992). Explaining the Gibbs sampler. The American Statistician, 46, 167174CrossRefGoogle Scholar
Chib, S., & Greenberg, E. (1995). Understanding the Metropolis-Hastings algorithm. The American Statistician, 49, 327335CrossRefGoogle Scholar
DiBello, L.V., Stout, W.F., & Roussos, L.A. (1995). Unified cognitive/psychometric diagnostic assessment likelihood-based classification techniques. In Nichols, P.D., Chipman, S.F., & Brennan, R.L. (Eds.), Cognitively diagnostic assessment (pp. 361389). Hillsdale, NJ: ErlbaumGoogle Scholar
Doignon, J.P., & Falmagne, J.C. (1999). Knowledge spaces. New York: Springer-VerlagCrossRefGoogle Scholar
Doornik, J.A. (2002). Object-oriented matrix programming using Ox (Version 3.1). [Computer software]. London: Timberlake Consultants PressGoogle Scholar
Draney, K.L., Pirolli, P., & Wilson, M. (1995). A measurement model for complex cognitive skill. In Nichols, P.D., Chipman, S.F., Brennan, R.L. (Eds.), Cognitively diagnostic assessment (pp. 103125). Hillsdale, NJ: ErlbaumGoogle Scholar
Embretson, S. (1984). A general latent trait model for response processes. Psychometrika, 49, 175186CrossRefGoogle Scholar
Embretson, S. (1997). Multicomponent response models. In van der Linden, W.J. & Hambleton, R.K. (Eds.), Handbook of modern item response theory (pp. 305321). New York: Springer-VerlagCrossRefGoogle Scholar
Everitt, B. S. (1998). The Cambridge dictionary of statistics. Cambridge, UK: Cambridge University PressGoogle Scholar
Fischer, G. H. (1995). The linear logistic test model. In Fischer, G. H. & Molenaar, I. W. (Eds.), Rasch models: Foundations, recent developments, and applications (pp. 131155). New York: Springer-VerlagCrossRefGoogle Scholar
Geman, S. & Geman, D. (1984). Stochastic relaxation, Gibbs distributions and the Bayesian restoration of images. IEEE Transactions on Pattern Analysis and Machine Intelligence, 6, 721741CrossRefGoogle ScholarPubMed
Gelman, A. & Rubin, D.B. (1992). Inference from iterative simulation using multiple sequences (with discussion). Statistical Science, 7, 457511CrossRefGoogle Scholar
Haertel, E.H. (1989). Using restricted latent class models to map the skill structure of achievement items. Journal of Educational Measurement, 26, 333352CrossRefGoogle Scholar
Hagenaars, J.A. (1990). Categorical longitudinal data: Loglinear panel, trend, and cohort analysis. Newbury Park, CA: SageGoogle Scholar
Hagenaars, J.A. (1993). Loglinear models with latent variables. Newbury Park, CA: SageCrossRefGoogle Scholar
Hartz, S. (2002). A Bayesian framework for the Unified Model for assessing cognitive abilities: Blending theory with practicality. Unpublished doctoral dissertation.Google Scholar
Junker, B.W. & Sijtsma, K. (2001). Cognitive assessment models with few assumptions, and connections with nonparametric item response theory. Applied Psychological Measurement, 25, 258272CrossRefGoogle Scholar
Macready, G.B., & Dayton, C. M. (1977). The use of probabilistic models in the assessment of mastery. Journal of Educational Statistics, 33, 379416Google Scholar
Maris, E. (1999). Estimating multiple classification latent class models. Psychometrika, 64, 187212CrossRefGoogle Scholar
Mislevy, R.J. (1996). Test theory reconceived. Journal of Educational Measurement, 33, 379416CrossRefGoogle Scholar
Muthén, B. (1978). Contribution to factor analysis of binary variables. Psychometrika, 43, 551560CrossRefGoogle Scholar
Patz, R.J., & Junker, B.W. (1999). A straightforward approach to Markov chain Monte Carlo methods for item response theory. Journal of Educational and Behavioral Statistics, 24, 146178CrossRefGoogle Scholar
Patz, R.J., & Junker, B.W. (1999). Applications and extensions of MCMC in IRT: Multiple item types, missing data, and rated responses. Journal of Educational and Behavioral Statistics, 24, 342366CrossRefGoogle Scholar
Raftery, A.E. (1995). Bayesian model selection in social research. Sociological Methodology, 25, 111163CrossRefGoogle Scholar
Raftery, A.E. (1996). Hypothesis testing and model selection. In Gilks, R. W., Richardson, S., & Spiegelhalter, D. J. (Eds.), Markov chain Monte Carlo in practice (pp. 163187). London: Chapman & HallGoogle Scholar
Reckase, M. (1997). A linear logistic multidimensional model for dichotomous item response data. In van der Linden, W.J. & Hambleton, R.K. (Eds.), Handbook of modern item response theory (pp. 271286). New York: Springer-VerlagCrossRefGoogle Scholar
Tatsuoka, C. (2002). Data-analytic methods for latent partially ordered classification models. Journal of the Royal Statistical Society Series C (Applied Statistics), 51, 337350CrossRefGoogle Scholar
Tatsuoka, K. (1985). A probabilistic model for diagnosing misconceptions in the pattern classification approach. Journal of Educational Statistics, 12, 5573CrossRefGoogle Scholar
Tatsuoka, K. (1990). Toward an integration of item-response theory and cognitive error diagnosis. In Frederiksen, N., Glaser, R., Lesgold, A., & Safto, M. (Eds.), Monitoring skills and knowledge acquisition (pp. 453488). Hillsdale, NJ: ErlbaumGoogle Scholar
Tatsuoka, K. (1995). Architecture of knowledge structures and cognitive diagnosis: A statistical pattern recognition and classification approach. In Nichols, P.D., Chipman, S.F., & Brennan, R.L. (Eds.), Cognitively diagnostic assessment (pp. 327359). Hillsdale, NJ: ErlbaumGoogle Scholar