Browse > Article
http://dx.doi.org/10.29220/CSAM.2021.28.6.627

Generalized nonlinear percentile regression using asymmetric maximum likelihood estimation  

Lee, Juhee (Department of Statistics, Kyungpook National University)
Kim, Young Min (Department of Statistics, Kyungpook National University)
Publication Information
Communications for Statistical Applications and Methods / v.28, no.6, 2021 , pp. 627-641 More about this Journal
Abstract
An asymmetric least squares estimation method has been employed to estimate linear models for percentile regression. An asymmetric maximum likelihood estimation (AMLE) has been developed for the estimation of Poisson percentile linear models. In this study, we propose generalized nonlinear percentile regression using the AMLE, and the use of the parametric bootstrap method to obtain confidence intervals for the estimates of parameters of interest and smoothing functions of estimates. We consider three conditional distributions of response variables given covariates such as normal, exponential, and Poisson for three mean functions with one linear and two nonlinear models in the simulation studies. The proposed method provides reasonable estimates and confidence interval estimates of parameters, and comparable Monte Carlo asymptotic performance along with the sample size and quantiles. We illustrate applications of the proposed method using real-life data from chemical and radiation epidemiological studies.
Keywords
asymmetric maximum likelihood estimation; nonlinear regression; percentile; quantile;
Citations & Related Records
연도 인용수 순위
  • Reference
1 Zietz J, Zietz EN, and Sirmans GS (2008). Determinants of house prices: a quantile regression approach, The Journal of Real Estate Finance and Economics, 37, 317-333.   DOI
2 Koenker R and Bassett Jr. G (1978). Regression quantiles, Econometrica: Journal of the Econometric Society, 46, 33-50.   DOI
3 Austin PC, Tu JV, Daly PA, and Alter DA (2005). The use of quantile regression in health care research: a case study examining gender differences in the timeliness of thrombolytic therapy, Statistics in medicine, 24, 791-816.   DOI
4 Draper NR and Smith H (1981). Applied Regression Analysis, John Wiley & Sons.
5 Efron B (1991). Regression percentiles using asymmetric squared error loss, Statistica Sinica, 1, 93-125.
6 Eide E and Showalter MH (1998). The effect of school quality on student performance: A quantile regression approach, Economics letters, 58, 345-350.   DOI
7 Geraci M and Bottai M (2007). Quantile regression for longitudinal data using the asymmetric Laplace distribution, Biostatistics, 8, 140-154.   DOI
8 Grant EJ, Brenner A, Sugiyama H, et al. (2017). Solid cancer incidence among the life span study of atomic bomb survivors: 1958-2009, Radiation Research, 187, 513-537.   DOI
9 Koenker R, Ng P, and Portnoy S (1994). Quantile smoothing splines, Biometrika, 81, 673-680.   DOI
10 Koenker R and Hallock KF (2001). Quantile regression. Journal of Economic Perspectives, 15, 143-156.   DOI
11 McCullagh P and Nelder JA (1989). Generalized Linear Models(2ed.), London: Chapman and Hall.
12 Preston DL, Ron E, Tokuoka S, et al. (2007). Solid cancer incidence in atomic bomb survivors: 1958-1998, Radiation Research, 168, 1-64.   DOI
13 Rodrigo H and Tsokos C (2020). Bayesian modelling of nonlinear Poisson regression with artificial neural networks, Journal of Applied Statistics, 47, 757-774.   DOI
14 He X, Ng P, and Portnoy S (1998). Bivariate quantile smoothing splines, Journal of the Royal Statistical Society: Series B (Statistical Methodology), 60, 537-550.   DOI
15 Koenker R and Park BJ (1996). An interior point algorithm for nonlinear quantile regression, Journal of Econometrics, 71, 265-283.   DOI
16 Wang J (2012). Bayesian quantile regression for parametric nonlinear mixed effects models, Statistical Methods & Applications, 21, 279-295.   DOI
17 Beyerlein A (2014). Quantile regression-opportunities and challenges from a user's perspective, American journal of epidemiology, 180, 330-331.   DOI
18 Efron B (1992). Poisson overdispersion estimates based on the method of asymmetric maximum likelihood, Journal of the American Statistical Association, 87, 98-107.   DOI
19 Geraci M (2019). Modelling and estimation of nonlinear quantile regression with clustered data, Computational statistics & data analysis, 136, 30-46.   DOI
20 Karlsson A (2007). Nonlinear quantile regression estimation of longitudinal data, Communications in Statistics-Simulation and Computation, 37, 114-131.   DOI
21 Newey W and Powell J (1987). Asymmetric least squares estimation and testing, Econometrica, 55, 819-47.   DOI
22 Smith H and Dubey SD (1964). Some reliability problems in the chemical industry, Industrial Quality Control, 22, 64-70.