GDUS-Modified Topp-Leone Distribution: A New Distribution with Increasing, Decreasing, and Bathtub Hazard Functions

  • Arun Kaushik Department of Statistics, Banaras Hindu University, Varanasi, India
  • Unnati Nigam Department of Statistics, Banaras Hindu University, Varanasi, India
Keywords: Probability distribution, identifiability, stochastic ordering, entropy, stress-strength reliability, simulation study, real data fitting

Abstract

In this paper, we propose an extension to the Topp-Leone distribution, as introduced by [20] using the Generalized-DUS transformation given by [8]. The Topp-Leone distribution is defined on interval (0,1) and has a characteristic J-shaped frequency curve. The newly extended version of Topp-Leone distribution accommodates a variety of shapes of hazard rate functions making it a versatile distribution. We have also derived explicit expressions for some properties like ordinary moments, conditional moments, distribution of order statistics, quantiles, mean deviation, and entropy. Further, we have also discussed results on identifiability, stress-strength reliability, and stochastic ordering that are concerned with two independent random variables. For inference regarding the unknown parameters of the distribution, we derive the equations which give their maximum likelihood estimators. We also present the asymptotic confidence intervals of the unknown parameters of the distribution, based on large sample property, using the Fisher information matrix. To facilitate further studies, a step-by-step algorithm is presented to produce a random sample from the distribution. Further, extensive simulation experiments are done to study the long-term behavior of the maximum likelihood estimators of the parameters through their mean squared error and mean absolute bias on the basis of large number of samples. The consistency of the MLEs is empirically proved. Lastly, the application of the proposed distribution is shown by fitting a real-life dataset over some existing distributions in the same range.

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Author Biographies

Arun Kaushik, Department of Statistics, Banaras Hindu University, Varanasi, India

Arun Kaushik is currently working as an Assistant Professor in the Department of Statistics, Banaras Hindu University, Varanasi, India. He completed his PhD in Statistics in 2016. His research interests span the areas of Bayesian Inference, decision theory, MCMC, distribution theory, Bayesian econometrics, Python language, and STAN Software applications. He has been a recipient of CSIR JRF and CSIR SRF during PhD.

Unnati Nigam, Department of Statistics, Banaras Hindu University, Varanasi, India

Unnati Nigam is currently a Masters’ degree student in the Department of Statistics, Banaras Hindu University, Varanasi, India. She completed her graduation from the same university in the year 2020 with a Gold Medal. She aspires to research and contribute in the areas of Statistical Inference, Bayesian Inference, Lifetime Data Analysis, Distribution Theory and R-software applications.

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Published
2022-05-07
Section
Articles