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Communications in Statistics: Case Studies, Data Analysis and Applications Volume 7, 2021 - Issue 2
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Article

Modeling road traffic accidents in Mauritius using clustered longitudinal COM-Poisson with gamma random effects

Naushad Mamode Khana Department of Economics and Statistics, Faculty of Social Sciences and Humanities, University of Mauritius, Réduit, Mauritius;
,
Ashwinee Devi Soobhugb Department of External Trade/Statistics Mauritius, Ministry of Finance, Economic Planning and Development, Port-Louis, MauritiusCorrespondence[email protected]
&
Zeinab Jannooa Department of Economics and Statistics, Faculty of Social Sciences and Humanities, University of Mauritius, Réduit, Mauritius;
Pages 113-127 | Published online: 07 Nov 2020

References

  • Ballinger, G. (2004). “Using Generalized Estimating Equations for Longitudinal Data Analysis.” Organizational Research Methods 7:127–50.
  • Bourgignon, M., J. Rodrigues, and M. Santos Neto. (2018). “Extended Poisson INAR(1) Processes with Equidispersion, Underdispersion and Overdispersion.” Journal of Applied Statistics 46:101–18.
  • Chanialidis, C. (2018). “Efficient Bayesian Inference for COM-Poisson Regression Models.” Statistics and Computing 28:595–608.
  • Chatla, S., and G. Shmueli. (2018). “Efficient Estimation of COM-Poisson Regression and a Generalized Additive Model.” Computational Statistics and Data Analysis 121:71–88.
  • Choo Wosoba, H., and S. Datta. (2018). “Analyzing Clustered Count Data with a Cluster-Specific Random Effect Zero-Inflated Conway-Maxwell-Poisson Distribution.” Journal of Applied Statistics 45 (5):799–814. doi: 10.1080/02664763.2017.1312299.
  • FitzMaurice, G., N. Laird, and A. Rotnizky. (1993). “Regression Models for Discrete Longitudinal Responses.” Statistical Science 8:284–309.
  • Gonzales Barron, U., and F. Butler. (2011). “A Comparison between the Discrete Poisson-Gamma and Poisson-Lognormal Distributions to Characterise Microbial Counts in Foods.” Food Control 22:1279–86.
  • Gonzales Barron, U., V. Cadavez, and F. Butler. (2014). “Conducting Inferential Statistics for Low Microbial Counts in Foods Using the Poisson-Gamma Regression.” Food Control 37:385–94.
  • Guikema, S., and J. Coffelt. (2008). “A Flexible Count Data Regression Model for Risk Analysis.” Risk Analysis 28:213–23. doi: 10.1111/j.1539-6924.2008.01014.x.
  • Jowaheer, V. (2003). “Poisson-Lognormal Mixed Model Based Estimation in Clustered Longitudinal Count Data Analysis.” University of Mauritius Research Journal: Science and Technology 10:111–28.
  • Jowaheer, V., N. M. Khan, and Y. Sunecher. (2017). “A BINAR(1) Time Series Model with Cross-Correlated COM-Poisson Innovations.” Communications in Statistics—Theory and Methods 47 (5):1133–54.
  • Jowaheer, V., and B. Sutradhar. (2005). “On AR(1) Versus MA(1) Models for Non-Stationary Time Series of Poisson Counts: Part I (Theory).” WSEAS Transactions on Mathematics 4:359–62.
  • Khan, N. M. (2016). “A Robust Algorithm for Estimating Regression and Dispersion Parameters in Non-Stationary Longitudinally Correlated COM-Poisson.” Journal of Computational Mathematics 19 (1):25–36.
  • Khan, N. M., and V. Jowaheer. (2013). “Comparing Joint GQL Estimation and GMM Adaptive Estimation in COM-Poisson Longitudinal Regression Model.” Communications in Statistics—Simulation and Computation 42 (4):755–770.
  • Lord, D., S. Geedipally, and S. Guikema. (2010). “Extension of the Application of Conway-Maxwell Poisson Models: Analysing Traffic Crash Data Exhibiting Underdispersion.” Risk Analysis 30:1268–76. doi: 10.1111/j.1539-6924.2010.01417.x.
  • Lord, D., S. Guikema, and S. Geedipally. (2008). “Application of Conway–Maxwell–Poisson for Analyzing Motor Vehicle Crashes.” Accident Analysis and Prevention 40:1123–34. doi: 10.1016/j.aap.2007.12.003.
  • McKenzie, E. (1986). “Autoregressive Moving-Average Processes with Negative Binomial and Geometric Marginal Distributions.” Advanced Applied Probability 18:679–705.
  • Minka, T., G. Shmueli, J. Kadane, S. Borle. and P. Boatwright. (2003), “Computing with the COM-Poisson Distribution.” Technical Report, Carnegie Mellon University.
  • Nadarajah, S. (2009). “Useful Moment and CDF Formulations for the COM-Poisson Distribution.” Statistical Papers 50:617–22.
  • Prentice, R., and L. Zhao. (1991). “Estimating Equations for Parameters in Means and Covariances of Multivariate Discrete and Continuous Responses.” Biometrics 47:825–39.
  • Rodrigues, J., M. de Castro, V. G. Cancho, and N. Balakrishnan. (2009). “COM-Poisson Cure Rate Survival Models and an Application to a Cutaneous Melanoma Data.” Journal of Statistical Planning and Inference 139:3605–11.
  • Sellers, K., S. Borle, and G. Shmueli. (2012). “The COM-Poisson Model for Count Data: A Survey of Methods and Applications.” Applied Stochastic Models in Business and Industry 22:104–16.
  • Sellers, K., D. Morris, and N. Balakrishnan. (2016). “Bivariate Conway–Maxwell–Poisson Distribution: Formulation, Properties and Inference.” Journal of Multivariate Analysis 150:152–68.
  • Shmueli, G., T. Minka, J. Borle, and P. Boatwright. (2005). “A Useful Distribution for Fitting Discrete Data.” Journal of the Royal Statistical Society: Series C (Applied Statistics) 54 (1):127–42.
  • Shoukri, M., M. Asyali, R. Vandorp, and D. Kelton. (2004). “The Poisson Inverse Gaussian Regression Model in the Analysis of Clustered Counts Data.” Journal of Data Science 2:17–32.
  • Steutel, F., and K. Van Harn. (1979). “Discrete Analogues of Self-Decomposability and Stability.” The Annals of Probability 7:3893–99.
  • Sunecher, Y., N. M. Khan, and V. Jowaheer. (2017). “A GQL Estimation Approach for Analysing Non-Stationary Over-Dispersed BINAR(1) Time Series.” Journal of Statistical Computation and Simulation 87 (10):1911–24.
  • Sutradhar, B. (2011). Dynamic Mixed Models for Familial Longitudinal Data. 1st ed. New York: Springer-Verlag.
  • Sutradhar, B., and K. Das. (1999). “On the Efficiency of Regression Estimators in Generalised Linear Models for Longitudinal Data.” Biometrika 86:459–65.
  • Sutradhar, B., and V. Jowaheer. (2003). “On Familial Longitudinal Poisson Mixed Models with Gamma Random Effects.” Journal of Multivariate Analysis 87:398–412.
  • Sutradhar, B., and Z. Qu. (2008). “On Approximate Likelihood Inference in a Poisson Mixed Model.” Canadian Journal of Statistics 26:169–86.
  • Wang, Y., O. Murphy, M. Turgeon, Z. Wang, S. R. Bhatnagar, J. Schulz, and E. Moodie. (2015). “The Perils of Quasi-Likelihood Information Criteria.” Stat 4:246–54.
  • Wedderburn, R. (1974). “Quasi-Likelihood Functions, Generalized Linear Models, and the Gauss–Newton Method.” Biometrika 61 (3): 439–47.
  • Zha, L., D. Lord, and Y. Zou. (2015). “The Poisson Inverse Gaussian (PIG) Generalized Linear Regression Model for Analyzing Motor Vehicle Crash Data.” Journal of Transportation Safety and Security 8:18–35.
  • Zhu, R., and H. Joe. (2009). “Modelling Heavy-Tailed Count Data Using a Generalised Poisson-Inverse Gaussian Family.” Statistics and Probability Letters 15:1695–703.

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