Restricted access

Research article

First published June 1992

A Generalized Partial Credit Model: Application of an EM Algorithm

Eiji MurakiView all authors and affiliations

Volume 16, Issue 2

https://doi.org/10.1177/014662169201600206

Abstract

The partial credit model (PCM) with a varying slope parameter is developed and called the generalized partial credit model (GPCM). The item step parameter of this model is decomposed to a location and a threshold parameter, following Andrich's (1978) rating scale formulation. The EM algorithm for estimating the model parameters is derived. The performance of this generalized model is compared on both simulated and real data to a Rasch family of polytomous item response models. Simulated data were generated and then analyzed by the various polytomous item response models. The results demonstrate that the rating formulation of the GPCM is quite adaptable to the analysis of polytomous item responses. The real data used in this study consisted of the National Assessment of Educational Progress (Johnson & Allen, 1992) mathematics data that used both dichotomous and polytomous items. The PCM was applied to these data using both constant and varying slope parameters. The GPCM, which provides for varying slope parameters, yielded better fit to the data than did the PCM.

Get full access to this article

View all access and purchase options for this article.

References

Andrich, D. (1978). A rating formulation for ordered response categories . Psychometrika, 43, 561-573.

Andrich, D. (1982). An extension of the Rasch model for ratings providing both location and dispersion parameters. Psychometrika, 47, 105-113.

Andrich, D. (1988). A general form of Rasch's extended logistic model for partial credit scoring. Applied Measurement in Education, 1, 363-378.

Birnbaum, A. (1968). Some latent trait models and their use in inferring an examinee's ability. In F. M. Lord and M. R. Novick, Statistical theories of mental test scores (pp. 397-479). Reading MA: Addison-Wesley.

Bock, R.D. (1972). Estimating item parameters and latent ability when responses are scored in two or more nominal categories. Psychometrika, 37, 29-51.

Bock, R.D., & Aitkin, M. (1981). Marginal maximum likelihood estimation of item parameters: Application of an EM algorithm. Psychometrika, 46, 443-459.

Bock, R.D., Gibbons, R., & Muraki, E. (1988). Full-information factor analysis. Applied Psychological Measurement, 12, 261-280.

Dempster, A.P., Laird, N.M., & Rubin, D.B. (1977). Maximum likelihood from incomplete data via the EM algorithm. Journal of the Royal Statistical Society, 39, (Series B), 1-38.

Johnson, E.G., & Allen, N.L. (1992). The NAEP 1990 technical report (No. 21-TR-20) . Princeton NJ: Educational Testing Service, National Assessment of Educational Progress.

Kendall, M.G., & Stuart, A. (1973). The advanced theory of statistics (Vol. 2). New York: Hafner .

Lord, F.M. (1980). Application of item response theory to practical testing problems. Hillsdale NJ: Erlbaum.

Masters, G.N. (1982). A Rasch model for partial credit scoring. Psychometrika, 47, 149-174.

Mislevy, R., & Bock, R.D. (1990). PC BILOG 3: Item analysis and test scoring with binary logistic models (2nd ed.). Chicago IL: Scientific Software, Inc.

Muraki, E. (1985, March). Full-information factor analysis for polytomous item response. Paper presented at the annual meeting of the American Educational Research Association, Chicago IL.

Muraki, E. (1990a). Fitting a polytomous item response model to Likert-type data. Applied Psychological Measurement, 14, 59-71.

Muraki, E. (1990b). RESGEN: Item response generator. Princeton NJ: Educational Testing Service.

Muraki, E., & Bock, R.D. (1991). PARSCALE: Parameter scaling of rating data. Chicago IL: Scientific Software, Inc.

Muraki, E., & Wang, M. (1992, April). Issues relating to the marginal maximum likelihood estimation of the partial credit model. Paper presented at the annual meeting of the American Educational Research Association, San Francisco CA.

Rasch, G. (1960). Probabilistic models for some intelligence and attainment tests. Copenhagen: Den-marks Paedagogiske Institut (Reprinted by University of Chicago Press, 1980).

Samejima, F. (1969). Estimation of latent trait ability using a response pattern of graded scores. Psychometrika Monograph Supplement, No. 17.

Samejima, F. (1972). A general model for free-response data. Psychometrika Monograph, No. 18.

Stroud, A.H., & Secrest, D. (1966). Gaussian quadrature formulas. Englewood Cliffs NJ: Prentice Hall.

Thissen, D., & Steinberg, L. (1986). A taxonomy of item response models. Psychometrika, 51, 567-577.

Wright, B.D., & Stone, M.H. (1979). Best test design. Chicago: MESA.

Cite article

Cite article

OR

If you have citation software installed, you can download article citation data to the citation manager of your choice

Information, rights and permissions

Information

Published In

Applied Psychological Measurement

Volume 16, Issue 2

Pages: 159 - 176

Article first published: June 1992

Issue published: June 1992

Keywords

Rights and permissions

Request permissions for this article.

Request Permissions

Authors

Affiliations

Eiji Muraki

Educational Testing Service

View all articles by this author

Metrics and citations

Metrics

This article was published in Applied Psychological Measurement.

View All Journal Metrics

Total views and downloads: 752

^*Article usage tracking started in December 2016

Receive email alerts when this article is cited

Sign up to citation alerts

Web of Science: 958 view articles Opens in new tab

Crossref: 968

Measuring grammatical understanding
Go to citation Crossref Google Scholar
Beyond a Unidimensional Measure: Unveiling the Multidimensional Structure of the Perceived Stress Scale
Go to citation Crossref Google Scholar
Structural validity of the Anxiety Symptom Scale – a Danish validation study
Go to citation Crossref Google Scholar
Severity Benchmarks for the Level of Personality Functioning Scale—Brief Form 2.0 (LPFS-BF 2.0) in Polish Adults
Go to citation Crossref Google Scholar
Semi-Parametric Item Response Theory With O’Sullivan Splines for Item Responses and Response Time
Go to citation Crossref Google Scholar
A scale for evaluating the willingness of national forest farm to participate in forest carbon sink project
Go to citation Crossref Google Scholar
An efficient PG-INLA algorithm for the Bayesian inference of logistic item response models
Go to citation Crossref Google Scholar
Implementation Aspects in Simulation Extrapolation-Based Stocking–Lord Linking
Go to citation Crossref Google Scholar
Linking Error Estimation in Haberman Linking
Go to citation Crossref Google Scholar
IRT Observed‐Score Equating for Rater‐Mediated Assessments Using a Hierarchical Rater Model
Go to citation Crossref Google Scholar
View More

Figures and tables

Figures & Media

Tables

View Options

If you have access to journal content via a personal subscription, university, library, employer or society, select from the options below:

Sage Journals profile

Sign in

Access personal subscriptions, purchases, paired institutional or society access and free tools such as email alerts and saved searches.

Required fields

Email:

Password:

Remember me

Forgotten your password?

OR

Institution

Society

Alternatively, view purchase options below:

Purchase access

Purchase 24 hour online access to view and download content.

Article - $37.50

Issue - $225.66

Subscribe to this journal

Read with DeepDyve

View options

PDF/EPUB

You currently have no access to this content. Visit the access options page to authenticate.