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http://dx.doi.org/10.7465/jkdi.2013.24.3.651

Quadratic inference functions in marginal models for longitudinal data with time-varying stochastic covariates  

Cho, Gyo-Young (Department of Statistics, Kyungpook National University)
Dashnyam, Oyunchimeg (Department of Statistics, Kyungpook National University)
Publication Information
Journal of the Korean Data and Information Science Society / v.24, no.3, 2013 , pp. 651-658 More about this Journal
Abstract
For the marginal model and generalized estimating equations (GEE) method there is important full covariates conditional mean (FCCM) assumption which is pointed out by Pepe and Anderson (1994). With longitudinal data with time-varying stochastic covariates, this assumption may not necessarily hold. If this assumption is violated, the biased estimates of regression coefficients may result. But if a diagonal working correlation matrix is used, irrespective of whether the assumption is violated, the resulting estimates are (nearly) unbiased (Pan et al., 2000).The quadratic inference functions (QIF) method proposed by Qu et al. (2000) is the method based on generalized method of moment (GMM) using GEE. The QIF yields a substantial improvement in efficiency for the estimator of ${\beta}$ when the working correlation is misspecified, and equal efficiency to the GEE when the working correlation is correct (Qu et al., 2000).In this paper, we interest in whether the QIF can improve the results of the GEE method in the case of FCCM is violated. We show that the QIF with exchangeable and AR(1) working correlation matrix cannot be consistent and asymptotically normal in this case. Also it may not be efficient than GEE with independence working correlation. Our simulation studies verify the result.
Keywords
FCCM assumption; GEE; longitudinal data; marginal model; QIF; time-varying stochastic covariates;
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1 Davis, C. S. (2002). Statistical methods for the analysis of repeated measurements, Springer-Verlag, New York.
2 Diggle, P. J., Heagerty, P., Liang, K-Y. and Zeger, S. L. (2002). Analysis of longitudinal data, Oxford University Press, New York.
3 Fitzmaurice, G. M, Liard, N.M. and Ware, J.H. (2004). Applied longitudinal analysis, Wiley, New York.
4 Fitzmaurice, G. M. (1995). A caveat concerning independence estimating equations with multivariate binary data. Biometrics, 51, 309-317.   DOI   ScienceOn
5 Lai, Tz. L. and Small, D. (2007). Marginal regression analysis of longitudinal data with time-dependent covariates: A generalised method of moments approach. Journal of the Royal Statistical Society B, 69, 79-99.
6 Pan, W., Thomas, A. L. and John, E. C. (2000). Note on marginal linear regression with correlated response data. The American Statistician. 54, 191-195.
7 Pepe, M. S. and Anderson, G. L. (1994). A cautionary note on inference for marginal regression models with longitudinal data and general correlated response data. Communications in Statistics-Simulation, 23, 939-951.   DOI   ScienceOn
8 Song, P. X.-K., Jiang, Z., Park, E. J. and Qu, A. (2009) Quadratic inference functions in marginal models for longitudinal data. Statistical Medicine, 28, 3683-3696   DOI   ScienceOn
9 Qu, A., Lindsay, B. G. and Li, B. (2000). Improving generalized estimating equations using quadratic inference functions. Biometrika, 87, 823-836.   DOI   ScienceOn
10 Qu, A. and Lindsay, B.G. (2003). Building adaptive estimating equation when inverse of covariance estimation is difficult. Journal of the Royal Statistical Society B, 65, 127-142.   DOI   ScienceOn