Theoretical and applied researchers have been frequently interested in proposing alternative skewed and symmetric lifetime parametric models that provide greater flexibility in modeling real-life data in several applied sciences. To fill this gap, we introduce a three-parameter bounded lifetime model called the exponentiated new power function (E-NPF) distribution. Some of its mathematical and reliability features are discussed. Furthermore, many possible shapes over certain choices of the model parameters are presented to understand the behavior of the density and hazard rate functions. For the estimation of the model parameters, we utilize eight classical approaches of estimation and provide a simulation study to assess and explore the as...
We introduce a new four-parameter distribution with constant, decreasing, increasing, bathtub and up...
In this article, we introduce a new lifetime model which exhibits the increasing, the decreasing and...
In this article, we introduce a new generalization of the Exponentiated Exponential distribution. Va...
In this paper we propose a new lifetime distribution which can handle bathtub-shaped unimodal increa...
In this paper, a potentiated lifetime model that demonstrates the bathtub-shaped hazard rate functio...
It is a common situation that the failure rate function has a bathtub shape for many mechanical and ...
In this study, we introduce an extended version of the modified Weibull distribution with an additio...
A new class of lifetime distributions, which can exhibit with upside-down bathtub-shaped, bathtub-sh...
A new lifetime distribution capable of modeling a bathtub-shaped hazard-rate function is proposed. T...
Modeling reliability data with nonmonotone hazards is a prominent research topic that is quite rich ...
The exponential power distribution (EP) is a lifetime model that can exhibit increasing and bathtub ...
In this paper we defined a new lifetime model called the the Exponentiated additive Weibull (EAW) di...
In this paper, we introduce a univariate four-parameter distribution. Several known distributions li...
A four-parameter extension of the generalized gamma distribution capable of modelling a bathtub-shap...
Bathtub failure rate shape is widely used in industrial and medical applications. In this paper, a t...
We introduce a new four-parameter distribution with constant, decreasing, increasing, bathtub and up...
In this article, we introduce a new lifetime model which exhibits the increasing, the decreasing and...
In this article, we introduce a new generalization of the Exponentiated Exponential distribution. Va...
In this paper we propose a new lifetime distribution which can handle bathtub-shaped unimodal increa...
In this paper, a potentiated lifetime model that demonstrates the bathtub-shaped hazard rate functio...
It is a common situation that the failure rate function has a bathtub shape for many mechanical and ...
In this study, we introduce an extended version of the modified Weibull distribution with an additio...
A new class of lifetime distributions, which can exhibit with upside-down bathtub-shaped, bathtub-sh...
A new lifetime distribution capable of modeling a bathtub-shaped hazard-rate function is proposed. T...
Modeling reliability data with nonmonotone hazards is a prominent research topic that is quite rich ...
The exponential power distribution (EP) is a lifetime model that can exhibit increasing and bathtub ...
In this paper we defined a new lifetime model called the the Exponentiated additive Weibull (EAW) di...
In this paper, we introduce a univariate four-parameter distribution. Several known distributions li...
A four-parameter extension of the generalized gamma distribution capable of modelling a bathtub-shap...
Bathtub failure rate shape is widely used in industrial and medical applications. In this paper, a t...
We introduce a new four-parameter distribution with constant, decreasing, increasing, bathtub and up...
In this article, we introduce a new lifetime model which exhibits the increasing, the decreasing and...
In this article, we introduce a new generalization of the Exponentiated Exponential distribution. Va...