Abstract
In this paper, we studied the problem of estimating the odd exponentiated half-logistic exponential (OEHLE) parameters using several frequentist estimation methods. Parameter estimation provides a guideline for choosing the best method of estimation for the model parameters, which would be very important for reliability engineers and applied statisticians. We considered eight estimation methods, called maximum likelihood, maximum product of spacing, least squares, Cramér–von Mises, weighted least squares, percentiles, Anderson–Darling, and right-tail Anderson–Darling for estimating its parameters. The finite sample properties of the parameter estimates are discussed using Monte Carlo simulations. In order to obtain the ordering performance of these estimators, we considered the partial and overall ranks of different estimation methods for all parameter combinations. The results illustrate that all classical estimators perform very well and their performance ordering, based on overall ranks, from best to worst, is the maximum product of spacing, maximum likelihood, Anderson–Darling, percentiles, weighted least squares, least squares, right-tail Anderson–Darling, and Cramér–von-Mises estimators for all the studied cases. Finally, the practical importance of the OEHLE model was illustrated by analysing a real data set, proving that the OEHLE distribution can perform better than some well known existing extensions of the exponential distribution.
Highlights
The exponential (E) distribution with its simple form, lack of memory property and only a constant hazard rate shape, has attracted many authors to develop more flexible and extended forms of the E distribution
In order to provide a guideline for choosing the best method of estimation for the odd exponentiated half-logistic exponential (OEHLE) parameters, which would be very important to reliability engineers and applied statisticians, we calculated the partial and overall ranks of all methods of estimation for different parameter combinations
We can conclude that the maximum product of spacing estimators (MPSEs) outperform all other estimators with an overall score of 35
Summary
The exponential (E) distribution with its simple form, lack of memory property and only a constant hazard rate shape, has attracted many authors to develop more flexible and extended forms of the E distribution. These extended forms are capable of modelling real data sets with decreasing, increasing, bathtub, decreasing–increasing, and unimodal failure rates which are very common in several applied areas such as reliability, medicine, and engineering, among others. Its probability density function (PDF) can be reversed-J shaped, symmetric, right-skewed and left-skewed. They investigated some of its fundamental properties such as quantile and generating
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
