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http://dx.doi.org/10.5351/CKSS.2010.17.6.845

Accuracy Measures of Empirical Bayes Estimator for Mean Rates  

Jeong, Kwang-Mo (Department of Statistics, Pusan National University)
Publication Information
Communications for Statistical Applications and Methods / v.17, no.6, 2010 , pp. 845-852 More about this Journal
Abstract
The outcomes of counts commonly occur in the area of disease mapping for mortality rates or disease rates. A Poisson distribution is usually assumed as a model of disease rates in conjunction with a gamma prior. The small area typically refers to a small geographical area or demographic group for which very little information is available from the sample surveys. Under this situation the model-based estimation is very popular, in which the auxiliary variables from various administrative sources are used. The empirical Bayes estimator under Poissongamma model has been considered with its accuracy measures. An accuracy measure using a bootstrap samples adjust the underestimation incurred by the posterior variance as an estimator of true mean squared error. We explain the suggested method through a practical dataset of hitters in baseball games. We also perform a Monte Carlo study to compare the accuracy measures of mean squared error.
Keywords
Disease rate; Poisson-gamma model; inverse dispersion parameter; negative binomial; empirical Bayes; small area estimation; mean squared error; bootstrap sample;
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  • Reference
1 Marshall, R. J. (1991). Mapping disease and mortality rates using empirical Bayes estimators, Applied Statistics, 40, 283–294.   DOI
2 Rao, J. N. K. (2003). Small Area Estimation, Wiley.
3 Steffey, D. and Kass, R. E. (1991). Comment on Robinson, G. K., “That BLUP is a Good Thing – The estimation of random effects,” Statistical Science, 6, 45–47.   DOI
4 Stern, H. S. and Sugano, A. (2007). Inference about batter-pitcher matchups in baseball from small samples. In: Albert, J. and Koning, R.H., Statistical Thinking in Sports, Chapman & Hall, 153–165.
5 Tsutakawa, R. K., Shoop, G. L. and Marienfeld, C. J. (1985). Empirical Bayes estimation of cancer disease rates, Statistics in Medicine, 4, 201–212.   DOI
6 Ghosh, M. and Rao, J. N. K. (1994). Small area estimation: An appraisal, Statistical Science, 9, 55–93.
7 Butar, F. B. and Lahiri, P. (2003). On measures of uncertainty of empirical Bayes small-area estimator, Journal of Statistical Planning and Inference, 112, 63–76.   DOI
8 Clayton, D. and Kaldor, J. (1987). Empirical Bayes estimates of age-standardized relative risks for use in disease mapping, Biometrics, 43, 671–681.   DOI
9 Efron, B. and Morris, C. (1975). Data analysis using Stein’s estimator and its generalizations, Journal of the American Statistical Association, 70, 311–319.   DOI
10 Gonzalez, M. E. (1973). Use and evaluation of synthetic estimators, In Proceedings of the Social Statistics Section, 33–36.
11 Jeong, K. M. and Yang, H. R. (2009). Dispersion parameter of Poisson-Gamma model in the small area estimation, Journal of the Korean Data Analysis Society, 11, 23–32.
12 Jiang, J., Lahiri, P. and Wan, S. M. (2002). A unified jackknife theory for empirical best prediction with M-estimation, The Annals of Statistics, 30, 1782–1810.   DOI
13 Lahiri, P. and Maiti, T. (2002). Empirical Bayes estimation of relative risks in disease mapping, Calcutta Statistical Association Bulletin, 53, 213–223.
14 Laird, N. M. and Louis, T. A. (1987). Empirical Bayes confidence intervals based on bootstrap samples, Journal of the American Statistical Association, 82, 739–750.   DOI