Abstract
In this work, we propose and study a new family of discrete distributions. Many useful mathematical properties, such as ordinary moments, moment generating function, cumulant generating function, probability generating function, central moment, and dispersion index are derived. Some special discrete versions are presented. A certain special case is discussed graphically and numerically. The hazard rate function of the new class can be “decreasing”, “upside down”, “increasing”, and “decreasing-constant-increasing (U-shape)”. Some useful characterization results based on the conditional expectation of certain function of the random variable and in terms of the hazard function are derived and presented. Bayesian and non-Bayesian methods of estimation are considered. The Bayesian estimation procedure under the squared error loss function is discussed. Markov chain Monte Carlo simulation studies for comparing non-Bayesian and Bayesian estimations are performed using the Gibbs sampler and Metropolis–Hastings algorithm. Four applications to real data sets are employed for comparing the Bayesian and non-Bayesian methods. The importance and flexibility of the new discrete class is illustrated by means of four real data applications.
Highlights
Introduction and GenesisDiscretization of existing continuous probability distributions have received noticeable attention in recent years
We compare the fits of the DRW model with some competitive models, such as discrete Weibull (DW), exponentiated discrete Weibull (EDW), discrete inverse Weibull (DIW), exponentiated discrete Lindley (EDLi), discrete Pareto (DPa), discrete Lindley (DLi)-II, and discrete log-logistic (DLL)
We presented and studied a new discrete analogue based on the continuous Rayleigh
Summary
Discretization of existing continuous probability distributions have received noticeable attention in recent years. We present and study a new discrete analogue based on the continuous. The probability mass function (PMF) of the discrete analogue of DRG family corresponding to (2). Many useful discretization processes can be applied to many existing continuous families (see [17,18,19,20,21,22,23,24]).
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