1. Introduction

In the field of statistical distribution theory, the practice of introducing additional parameters to existing distribution families has become widespread and highly valuable. By adding an extra parameter, statisticians are able to significantly enhance the flexibility of the underlying models, allowing them to better capture complex data patterns and provide improved fits to a variety of real-world phenomena. This approach not only enriches the mathematical structure of distributions but also extends their practical applications across numerous scientific and engineering disciplines.

Since the 1980s, the development of new probability distributions has largely focused on two principal strategies: one is the combination of existing distributions to create entirely new families and the other is the extension of classical distributions by introducing one or more extra parameters. The former method offers a way to blend the strengths of different models, while the latter provides a systematic enhancement of a given model’s flexibility without altering its core characteristics.

Adding new parameters often allows distributions to adapt to a broader range of shapes, including skewed, heavy-tailed or multi-modal data structures, which are frequently encountered in practice. Such improvements make the extended models particularly useful for applications in fields like survival analysis, reliability engineering, finance, environmental studies and biomedical research. Moreover, these extended families maintain a close connection to the baseline distributions, ensuring that the original models remain special or limiting cases within the new, more general, framework.

Overall, the introduction of additional parameters into existing distribution families continues to be a powerful and essential technique in statistical modeling. It not only broadens the theoretical landscape of probability distributions but also significantly enhances their practical utility in analyzing and interpreting real-world data.

One of the earliest and most fundamental techniques for generating new probability distributions was introduced in Reference [1], which proposed the exponentiated family of distributions. This approach enhances a baseline distribution by introducing an additional shape parameter, thereby increasing its flexibility to model a wider variety of data patterns. It is widely acknowledged that no single probability model consistently provides the best fit across all real-world scenarios. As a result, various fields in statistics continually seek to develop new probability models tailored to specific needs. Modified or newly developed distributions often offer better fitting capabilities compared to existing models, which motivates researchers to explore novel distributions applicable across diverse areas. The cumulative distribution function (CDF) of the exponentiated family is given by

(1)$F(x;\gamma ,\zeta )={\left[G(x;\zeta )\right]}^{\gamma },\gamma ,\zeta >0,x\in \mathbb{R}.$

Building on this idea, Reference [2] introduced the Marshall–Olkin family of distributions, aimed at further improving the flexibility of existing models. Their transformation modifies the baseline CDF using the parameter $\alpha$, resulting in the following CDF:

(2)${\overline{F}}_{MO}(\alpha ;x)={\displaystyle \frac{\alpha \overline{F}\left(x\right)}{1-\overline{\alpha }\overline{F}\left(x\right)}},\alpha >0,\overline{\alpha }=1-\alpha ,x\in \mathbb{R}.$

To introduce greater flexibility in probability modeling, Reference [3] proposed the alpha-power transformation (APT), which incorporates a new parameter $\alpha$ into the baseline distribution $G(x;\beta )$. The properties of the exponential distribution under this transformation were discussed as a special case. The CDF of the APT family is given by

(3)$F(x;\alpha ,\zeta )=\left\{\begin{array}{cc}{\displaystyle \frac{{\alpha }^{G(x;\zeta )}-1}{\alpha -1}},\hfill & \mathrm{if}\alpha >0,\alpha \ne 1,\hfill \\ G(x;\zeta ),\hfill & \mathrm{if}\alpha =1.\hfill \end{array}\right.$

(4)$F_{MIT}(x;\alpha )={\displaystyle \frac{\alpha F\left(x\right)}{1-\overline{\alpha }F\left(x\right)}},\alpha >0,\overline{\alpha }=1-\alpha ,x\in \mathbb{R}.$

(5)$F(x;\alpha ,\zeta )=1-\left(e^{\alpha G(x;\zeta )}-e^{\alpha }G(x;\zeta )\right),\alpha >0,x\in \mathbb{R}.$

(6)$F(x;\zeta )={\displaystyle \frac{e^{1-cos\left(\frac{\pi G(x;\zeta )}{1+G(x;\zeta )}\right)}-1}{e-1}},\zeta >0,x\in \mathbb{R}.$

(7)$F_{\mathrm{ASP}}(x;\alpha ,\zeta )=2sin\left({\displaystyle \frac{\pi }{2}}{\left[C(x;\zeta )\right]}^{\alpha }\right)-{\left[C(x;\zeta )\right]}^{\alpha },\alpha ,\zeta >0,x\in \mathbb{R}.$

(8)$F(x;\alpha ,\xi )={\displaystyle \frac{e^{\alpha G{(x;\xi )}^2}-1}{e^{\alpha }-1}},\alpha ,\xi >0,x\in \mathbb{R}.$

(9)$G\left(x\right)={\displaystyle \frac{{\beta }^{F^2\left(x\right)}{\alpha }^{F\left(x\right)}-1}{\alpha \beta -1}},\alpha ,\beta \ge 1,\alpha \beta \ne 1.$

(10)$G(x;\alpha ,\xi )={\displaystyle \frac{{\alpha }^{F(x;\xi )}-e^{F(x;\xi )}}{\alpha -e}},\xi >0,\alpha \ne e,\alpha >e,x\in \mathbb{R}.$

(11)$G\left(z\right)={\displaystyle \frac{{\alpha }^{F\left(z\right)}-{\beta }^{F\left(z\right)}}{\alpha -\beta }},z\in \mathbb{R},\alpha ,\beta >0,\alpha \ne \beta \ne 1.$

The NAP-X family is a transformation-based framework that systematically modifies baseline distributions to achieve superior adaptability. Unlike conventional methods relying on direct parameter expansion, it employs a controlled transformation mechanism to adjust shape and tail behavior. This enables the efficient modeling of both symmetric and asymmetric data patterns, making it a powerful tool for complex real-world phenomena across diverse fields.

As a specific illustration, we derive a modified half-logistic distribution via the NAP-X transformation. This model demonstrates enhanced performance, particularly in its probability density function (PDF) and hazard rate function (HRF). Comprehensive comparisons with established models—including the alpha-power exponential and Marshall–Olkin exponential distributions—using standard metrics (AIC, BIC, AICC, HQIC, K-S statistics) consistently show the superior flexibility and goodness of fit of the NAP-X model, detailed in the applications sections.

Overall, the NAP-X family preserves the theoretical elegance of classical distributions while offering a robust mechanism for capturing diverse data patterns. Its effective handling of symmetry and asymmetry renders it highly suitable for reliability analysis, survival studies, biomedical research and engineering systems.

The manuscript is structured as follows:

Section 2: Presents the motivation behind this study and highlights the research gap addressed by the proposed NAP-X family of distributions.

A defining feature of the NAP-X family is its introduction of a shape parameter $\alpha >0$ to generalize baseline distributions. This parameter enables the modeling of diverse behaviors such as skewness, varying tail weights and flexible hazard rate shapes, often inadequately captured by standard models. Crucially, the baseline distribution is retained as the special case when $\alpha =1$, ensuring the NAP-X family is a true generalization that preserves baseline properties while offering enhanced flexibility. This makes it particularly valuable for survival analysis, reliability studies and industrial data modeling.

2. Motivation and Research Gap

The advancement of statistical modeling, particularly in reliability and survival analysis, has led to the creation of numerous flexible probability distributions. These models aim to better capture real-world data behavior, especially in terms of skewness, kurtosis and hazard rate dynamics. A popular method to achieve flexibility involves transforming existing baseline distributions using functional techniques such as the exponentiated, Marshall–Olkin, alpha-power, beta-generated and transmutation approaches.

While these approaches have yielded substantial improvements in model fitting, they often come at the cost of excessive parameterization. The addition of multiple parameters can lead to interpretational difficulties, overfitting, numerical instability in estimation and challenges in model selection. Furthermore, many classical transformations lack the ability to simultaneously control symmetry and tail behavior in a simple yet effective manner.

In particular, the alpha-power transformation, despite its wide applicability, has limited structural flexibility when applied directly. It modifies tail behavior but does not consistently enhance hazard rate shapes or allow symmetric modeling. Moreover, transformations such as the Marshall–Olkin method tend to create abrupt changes in distribution structure, which may not be suitable for gradual changes observed in empirical data.

To address these limitations, there is a need for a new transformation technique with the following properties:

Enhances baseline distributions while maintaining parsimony (i.e., minimal parameter addition);

3. Novel Alpha-Power X Family and Properties

In this section, we introduce a novel and flexible class of probability distributions, termed the novel alpha-power (NAP) X family. The primary objective behind the formulation of this family is to enhance the adaptability of existing probabilistic models by integrating an additional shape parameter. This newly introduced parameter enables simultaneous control over the shape and scale features of a given baseline distribution, thereby offering improved modeling capabilities for complex real-world data encountered in diverse domains such as engineering, finance and survival analysis.

The NAP-X family is generated by applying a transformation to the cumulative distribution function (CDF) of a baseline distribution, denoted by $H\left(x\right)$. This transformation incorporates a shape parameter $\alpha >0$, which plays a crucial role in regulating the tail behavior and improving the overall flexibility of the resulting distribution. Mathematically, the CDF of the NAP-X family is expressed as follows.

In order to determine whether Equation (12) is accurate, we must prove the following lemma.

3.1. Novel Alpha-Power Half-Logistic Model

In this subsection of the article, a particular subclass of the NAP-X family, characterized by two parameters, is introduced. We refer to this particular model as the novel alpha-power half-logistic (NAP-HL) model.

The CDF $H\left(x\right)$ and PDF $h\left(x\right)$ of the half-logistic distribution are defined as follows:

(14)$H\left(x\right)={\displaystyle \frac{1-e^{-\theta x}}{1+e^{-\theta x}}},\mathrm{so}1-H\left(x\right)={\displaystyle \frac{2e^{-\theta x}}{1+e^{-\theta x}}}$

(15)$h\left(x\right)={\displaystyle \frac{2\theta e^{-\theta x}}{{(1+e^{-\theta x})}^2}}$

(16)$F\left(x\right)={\displaystyle \frac{{\alpha }^{1-{\left(\frac{1-e^{-\theta x}}{1+e^{-\theta x}}\right)}^{\alpha }}-\alpha }{1-\alpha }},x>0,\alpha >0,\alpha \ne 1.$

(17)$f\left(x\right)={\displaystyle \frac{\alpha log\alpha }{\alpha -1}}{\left({\displaystyle \frac{1-e^{-\theta x}}{1+e^{-\theta x}}}\right)}^{\alpha -1}{\displaystyle \frac{2\theta e^{-\theta x}}{{(1+e^{-\theta x})}^2}}{\alpha }^{1-{\left({\displaystyle \frac{1-e^{-\theta x}}{1+e^{-\theta x}}}\right)}^{\alpha }},x>0,\alpha >0,\alpha \ne 1.$

(18)$S\left(x\right)={\displaystyle \frac{1-{\alpha }^{1-{\left(\frac{1-e^{-\theta x}}{1+e^{-\theta x}}\right)}^{\alpha }}}{1-\alpha }}.$

(19)$h\left(x\right)={\displaystyle \frac{\alpha log\alpha }{{\alpha }^{1-{\left(\frac{1-e^{-\theta x}}{1+e^{-\theta x}}\right)}^{\alpha }}-1}}{\left({\displaystyle \frac{1-e^{-\theta x}}{1+e^{-\theta x}}}\right)}^{\alpha -1}{\displaystyle \frac{2\theta e^{-\theta x}}{{(1+e^{-\theta x})}^2}}{\alpha }^{1-{\left({\displaystyle \frac{1-e^{-\theta x}}{1+e^{-\theta x}}}\right)}^{\alpha }}.$

(20)$m\left(x\right)={\displaystyle \frac{\alpha log\alpha }{\alpha -{\alpha }^{1-{\left(\frac{1-e^{-\theta x}}{1+e^{-\theta x}}\right)}^{\alpha }}}}{\left({\displaystyle \frac{1-e^{-\theta x}}{1+e^{-\theta x}}}\right)}^{\alpha -1}{\displaystyle \frac{2\theta e^{-\theta x}}{{(1+e^{-\theta x})}^2}}{\alpha }^{1-{\left({\displaystyle \frac{1-e^{-\theta x}}{1+e^{-\theta x}}}\right)}^{\alpha }}.$

(21)$H\left(x\right)=log\left\{{\displaystyle \frac{1-\alpha }{1-{\alpha }^{1-{\left(\frac{1-e^{-\theta x}}{1+e^{-\theta x}}\right)}^{\alpha }}}}\right\}$

(22)$X_u=-{\displaystyle \frac{1}{\theta }}log\left\{{\displaystyle \frac{log\left[\frac{1}{u(1-\alpha )+\alpha }\right]}{log\left(\frac{{\alpha }^2}{u(1-\alpha )+\alpha }\right)}}\right\};0<u<1.$

3.1.1. Expansion Form

The PDF of the NAP-HL model can be written as

(23)$f\left(x\right)={\displaystyle \frac{{\alpha }^{2}log\alpha }{\alpha -1}}{\left({\displaystyle \frac{1-e^{-\theta x}}{1+e^{-\theta x}}}\right)}^{\alpha -1}{\displaystyle \frac{2\theta e^{-\theta x}}{{(1+e^{-\theta x})}^2}}{\alpha }^{-{\left({\displaystyle \frac{1-e^{-\theta x}}{1+e^{-\theta x}}}\right)}^{\alpha }}$

(24)${\alpha }^{-x}=\sum _{k=0}^{\infty }{\displaystyle \frac{{(-1)}^k{(log\alpha )}^k{x}^k}{k!}};\left|x\right|<1.$

(25)$\begin{array}{cc}\hfill f\left(x\right)& ={\displaystyle \frac{2{\alpha }^2\theta log\alpha }{\alpha -1}}\sum _{k=0}^{\infty }{\displaystyle \frac{{(-1)}^k{(log\alpha )}^k}{k!}}{\displaystyle \frac{{(1-e^{-\theta x})}^{\alpha (k+1)-1}}{{(1+e^{-\theta x})}^{\alpha (k+1)+1}}}{e}^{-\theta x}.\hfill \end{array}$

${(1-x)}^r=\sum _{p=0}^{\infty }\left({\displaystyle \genfrac{}{}{0pt}{}{r}{p}}\right){(-1)}^p{x}^p,;\left|x\right|<1$

${(1+x)}^{-s}=\sum _{q=0}^{\infty }{(-1)}^q\left({\displaystyle \genfrac{}{}{0pt}{}{s+q-1}{q}}\right)x^q;\left|x\right|<1.$

(26)$\begin{array}{cc}\hfill f\left(x\right)& ={\displaystyle \frac{2{\alpha }^2\theta }{\alpha -1}}\sum _{k=0}^{\infty }\sum _{p=0}^{\infty }\sum _{q=0}^{\infty }{\displaystyle \frac{{(-1)}^{k+p+q}{(log\alpha )}^{k+1}}{k!}}\left({\displaystyle \genfrac{}{}{0pt}{}{\alpha (k+1)-1}{p}}\right)\left({\displaystyle \genfrac{}{}{0pt}{}{\alpha (k+1)+k}{q}}\right)e^{-\theta (p+q+1)x}.\hfill \end{array}$

(27)${\delta }_{k,p,q}={\displaystyle \frac{{(-1)}^{k+p+q}{(log\alpha )}^{k+1}}{k!}}\left({\displaystyle \genfrac{}{}{0pt}{}{\alpha (k+1)-1}{p}}\right)\left({\displaystyle \genfrac{}{}{0pt}{}{\alpha (k+1)+k}{q}}\right).$

(28)$f\left(x\right)={\displaystyle \frac{2{\alpha }^2\theta }{\alpha -1}}\sum _{k,p,q=0}^{\infty }{\delta }_{k,p,q}{e}^{-\theta (p+q+1)x}.$

3.1.2. Moments and Moment Generating Function

For the NAP-HL model, the ordinary rth moment is calculated as

(29)${{\mu }_r}^{\prime }={\int }_0^{\infty }{x}^{r}f\left(x\right)dx.$

(30)${{\mu }_r}^{\prime }={\displaystyle \frac{2{\alpha }^2\theta }{\alpha -1}}\sum _{k,p,q=0}^{\infty }{\delta }_{k,p,q}{\displaystyle \frac{\Gamma (r+1)}{{\left((p+q+1)\theta \right)}^{r+1}}}$

(31)${{\mu }_1}^{\prime }={\displaystyle \frac{2{\alpha }^2\theta }{\alpha -1}}\sum _{k,p,q=0}^{\infty }{\delta }_{k,p,q}{\displaystyle \frac{1}{{\left((p+q+1)\theta \right)}^2}}$

(32)$M_X\left(t\right)=\sum _{r=0}^{\infty }{\displaystyle \frac{t^r}{r!}}E\left(X^r\right)$

(33)$M_X\left(t\right)={\displaystyle \frac{2{\alpha }^2\theta }{\alpha -1}}\sum _{k,p,q,r=0}^{\infty }{\delta }_{k,p,q}{\displaystyle \frac{t^r}{r!}}{\displaystyle \frac{\Gamma (r+1)}{{\left((p+q+1)\theta \right)}^{r+1}}}$

3.1.3. rth Incomplete Moment

The rth incomplete moment is defined as

(34)${\varphi }_r\left(z\right)=\underset{0}{\overset{z}{\int }}{x}^{r}f\left(x\right)dx$

(35)${\varphi }_r\left(z\right)={\displaystyle \frac{2{\alpha }^2\theta }{\alpha -1}}\sum _{k,p,q=0}^{\infty }{\delta }_{k,p,q}{\displaystyle \frac{1}{{\left((p+q+1)\theta \right)}^{r+1}}}\gamma \left((p+q+1)\theta \right),r+1).$

(36)${\varphi }_1\left(z\right)={\displaystyle \frac{2{\alpha }^2\theta }{\alpha -1}}\sum _{k,p,q=0}^{\infty }{\delta }_{k,p,q}{\displaystyle \frac{1}{{\left((p+q+1)\theta \right)}^2}}\gamma \left((p+q+1)\theta \right),2).$

3.1.4. Mean Residual Life (MRL) and Mean Waiting Time (MWT)

The MRL for the NAP-HL model is given by

$\mu \left(t\right)={\displaystyle \frac{1-\alpha }{1-{\alpha }^{1-{\left(\frac{1-e^{-\theta x}}{1+e^{-\theta x}}\right)}^{\alpha }}}}\left[{\displaystyle \frac{2{\alpha }^2\theta }{\alpha -1}}\sum _{k,p,q=0}^{\infty }{\delta }_{k,p,q}{\displaystyle \frac{1}{{\left((p+q+1)\theta \right)}^2}}\left(1-\gamma \left(\right(p+q+1\left)\theta \right),2)\right)\right]-t$

(37)$\overline{\mu }\left(t\right)=t-{\displaystyle \frac{2{\alpha }^2\theta {\sum }_{k,p,q=0}^{\infty }{\delta }_{k,p,q}\frac{1}{{\left((p+q+1)\theta \right)}^2}\gamma \left((p+q+1)\theta \right),2)}{\alpha -{\alpha }^{1-{\left(\frac{1-e^{-\theta x}}{1+e^{-\theta x}}\right)}^{\alpha }}}}$

3.1.5. Rényi Entropy

The Rényi entropy of order $\varphi$ for the NAP-HL model is defined as

(38)$R_{\varphi }={\displaystyle \frac{1}{1-\varphi }}log\left[{\int }_0^{\infty }f{\left(x\right)}^{\varphi }dx\right],\varphi >0,\varphi \ne 1,x\in \mathbb{R}.$

(39)$R_{\varphi }={\displaystyle \frac{1}{1-\varphi }}log\left\{{\left[{\displaystyle \frac{2{\alpha }^2\theta }{\alpha -1}}\sum _{k,p,q=0}^{\infty }{\delta }_{k,p,q}\right]}^{\varphi }·{\displaystyle \frac{1}{\theta (p+q+1)\varphi }}\right\},\varphi >0,\varphi \ne 1.$

3.1.6. Tsallis q-Entropy

The Tsallis entropy (also called q-entropy) of order $\varphi$ for the NAP-HL model, using the expansion in Equation (28), is given by

(40)$Q_{\varphi }={\displaystyle \frac{1}{\varphi -1}}\left[1-{\left({\displaystyle \frac{2{\alpha }^2\theta }{\alpha -1}}\sum _{k,p,q=0}^{\infty }{\delta }_{k,p,q}\right)}^{\varphi }·{\displaystyle \frac{1}{\theta (p+q+1)\varphi }}\right],\varphi >0,\varphi \ne 1.$

3.2. Order Statistics

Suppose $X_1,X_2,\dots ,X_n$ denote the random variables which are independently and identically drawn from the sample sizes n with the PDF and CDF defined, respectively, in Equation (17) and Equation (16). The $m^{\mathrm{th}}$-order statistics of those variables $f_{m,k}\left(x\right)$ is defined as

(41)$f_{m,k}\left(x\right)={\displaystyle \frac{k!}{(m-1)!(k-m)!}}f\left(x\right){\left[F\left(x\right)\right]}^{m-1}{[1-F\left(x\right)]}^{k-m}.$

(42)$\begin{array}{cc}\hfill f_{m,k}\left(x\right)& ={\displaystyle \frac{k!}{(m-1)!(k-m)!}}·{\displaystyle \frac{2{\alpha }^2\theta }{\alpha -1}}\sum _{k,p,q=0}^{\infty }{\delta }_{k,p,q}{e}^{-\theta (p+q+1)x}\hfill \\ \hfill & \times {\displaystyle \frac{{\left[{\alpha }^{1-{\left(\frac{1-e^{-\theta x}}{1+e^{-\theta x}}\right)}^{\alpha }}-\alpha \right]}^{m-1}{\left[1-{\alpha }^{1-{\left(\frac{1-e^{-\theta x}}{1+e^{-\theta x}}\right)}^{\alpha }}\right]}^{k-m}}{{(1-\alpha )}^{k-1}}}\hfill \end{array}$

4. Estimation Approaches

In this section, various frequentist estimation methods are employed to address the problem of estimating the parameters of the NAP-HL model. Parameter estimation serves as a valuable tool for applied statisticians and reliability engineers, offering guidance in selecting an appropriate method for parameter inference. To estimate the parameters of the NAP-HL model, seven estimation techniques were considered, namely, maximum likelihood estimation (${\Delta }_1$), Cramér–von Mises estimation (${\Delta }_2$), maximum product of spacings estimation (${\Delta }_3$), ordinary least squares estimation (${\Delta }_4$), weighted least squares estimation (${\Delta }_5$), Anderson–Darling estimation (${\Delta }_6$), and right-tailed Anderson–Darling estimation (${\Delta }_7$).

4.1. Maximum Likelihood Estimation (${\Delta }_1$) for Complete Sample

Let the random variables $X_1,X_2,\dots ,X_n$ be a random sample from the NAP-HL model with PDF $f(x;\alpha ,\theta )$, as given in Equation (17). The likelihood function corresponding to $f(x;\alpha ,\theta )$, say $L(\alpha ,\theta )$, is given as

(43)$L(x;\alpha ,\theta )=\prod _{k=1}^n{\displaystyle \frac{\alpha log\alpha }{\alpha -1}}{\left({\displaystyle \frac{1-e^{-\theta x}}{1+e^{-\theta x}}}\right)}^{\alpha -1}{\displaystyle \frac{2\theta e^{-\theta x}}{{(1+e^{-\theta x})}^2}}{\alpha }^{1-{\left({\displaystyle \frac{1-e^{-\theta x}}{1+e^{-\theta x}}}\right)}^{\alpha }}$

$\begin{array}{cc}\hfill \ell (x;\alpha ,\theta )& =nln\left(\alpha \right)+nln\left(2\theta \right)+nln(ln\left(\alpha \right))-nln(\alpha -1)+(\alpha -1)\sum _{k=1}^{n}ln(1-e^{-\theta x_k})-(\alpha +1)\sum _{k=1}^{n}ln(1+e^{-\theta x_k})\hfill \\ \hfill & -\theta \sum _{k=1}^n{x}_k+\sum _{k=1}^n\left[1-{\left({\displaystyle \frac{1-e^{-\theta x_k}}{1+e^{-\theta x_k}}}\right)}^{\alpha }ln\alpha \right].\hfill \end{array}$

$\begin{array}{cc}\hfill {\displaystyle \frac{\partial }{\partial \alpha }}\ell (x;\alpha ,\gamma ,\eta )& ={\displaystyle \frac{n}{\alpha ln\alpha }}-{\displaystyle \frac{n}{\alpha (\alpha -1)}}+\sum _{k=1}^{n}ln(1-e^{-\theta x_k})-\sum _{k=1}^{n}ln(1-e^{-\theta x_k})\hfill \\ \hfill & +\sum _{k=1}^n{\displaystyle \frac{1}{\alpha }}\left[1-{\left({\displaystyle \frac{1-e^{-\theta x_k}}{1+e^{-\theta x_k}}}\right)}^{\alpha }\right]-ln\alpha \sum _{k=1}^n\left[{\left({\displaystyle \frac{1-e^{-\theta x_k}}{1+e^{-\theta x_k}}}\right)}^{\alpha }ln\left({\displaystyle \frac{1-e^{-\theta x_k}}{1+e^{-\theta x_k}}}\right)\right].\hfill \end{array}$

$\begin{array}{cc}\hfill {\displaystyle \frac{\partial }{\partial \theta }}\ell (x;\alpha ,\theta )& ={\displaystyle \frac{n}{2\theta }}+\sum _{k=1}^n{x}_k+(\alpha -1)\sum _{k=1}^n{\displaystyle \frac{x_k{e}^{-\theta x_k}}{ln(1-e^{-\theta x_k})}}+(\alpha +1)\sum _{k=1}^n{\displaystyle \frac{x_k{e}^{-\theta x_k}}{ln(1+e^{-\theta x_k})}}\hfill \\ \hfill & -2\alpha ln\alpha \sum _{k=1}^n{\left({\displaystyle \frac{1-e^{-\theta x_k}}{1+e^{-\theta x_k}}}\right)}^{\alpha -1}{\displaystyle \frac{x_k{e}^{-\theta x_k}}{{(1+e^{-\theta x_k})}^2}}.\hfill \end{array}$

4.2. Cramér–Von Mises Estimation (${\Delta }_2$)

A study conducted in [13] demonstrated that the Cramér–von Mises estimator (CVME) exhibits less bias compared to other minimum distance estimators. In this study, the CVME method is employed to estimate the parameters of the NAP-HL distribution. The CVME of the unknown parameters can be obtained by minimizing the following function:

$\begin{array}{cc}\hfill C(\alpha ,\theta )& ={\displaystyle \frac{1}{12n}}+\sum _{k=1}^n{\left[F\left(x_{\left(k\right)}\right)-{\displaystyle \frac{2k-1}{2n}}\right]}^2,\hfill \\ & ={\displaystyle \frac{1}{12n}}+\sum _{k=1}^{n+1}{\left[{\displaystyle \frac{{\alpha }^{1-{\left(\frac{1-e^{-\theta x_k}}{1+e^{-\theta x_{\left(k\right)}}}\right)}^{\alpha }}-\alpha }{1-\alpha }}-{\displaystyle \frac{2k-1}{2n}}\right]}^2.\hfill \end{array}$

4.3. Maximum Product of Spacing Estimation (${\Delta }_3$)

The maximum-product-of-spacings (MPS) approach was initially introduced in [14] as an alternative to the maximum likelihood estimation method for parameter estimation in continuous univariate distributions. Independently, Reference [15] also explored this method, highlighting its consistency and interpreting it as an estimator of the Kullback–Leibler information measure. By demonstrating the efficiency of the spacing technique and its consistency under broader conditions than those required for maximum likelihood estimation, Reference [14] provided compelling justification for the adoption of the MPS method in this study.

We now proceed to define the uniform spacings for a random sample drawn from the NAP-HL distribution. For a random sample of size n with order statistics $X_{\left(1\right)},X_{\left(2\right)},\dots ,X_{\left(n\right)}$, the uniform spacings are defined as the differences between consecutive order statistics, given by

$D_k=F\left(x_{\left(k\right)}\right)-F\left(x_{(k-1)}\right);k=1,2,...,n+1$

$\begin{array}{cc}\hfill M(\alpha ,\theta )& ={\displaystyle \frac{1}{n+1}}\sum _{k=1}^{n+1}ln\left[D_k\right]\hfill \\ & ={\displaystyle \frac{1}{n+1}}\sum _{k=1}^{n+1}ln\left[{\displaystyle \frac{{\alpha }^{1-{\left(\frac{1-e^{-\theta x_k}}{1+e^{-\theta x_k}}\right)}^{\alpha }}-\alpha }{1-\alpha }}-{\displaystyle \frac{{\alpha }^{1-{\left(\frac{1-e^{-\theta x_{k-1}}}{1+e^{-\theta x_{k-1}}}\right)}^{\alpha }}-\alpha }{1-\alpha }}\right].\hfill \end{array}$

4.4. Ordinary Least Square Estimation (${\Delta }_4$) and Weighted Least Square Estimation (${\Delta }_5$)

To estimate the parameters of probability models, Reference [16] proposed the use of ordinary least squares and weighted least squares estimation methods. The parameters of the proposed model can be estimated using the least squares estimation approach by minimizing the least squares function $S(\alpha ,\gamma ,\eta )$ with respect to the unknown parameters, where

$\begin{array}{cc}\hfill S(\alpha ,\theta )& =\sum _{k=1}^n{\left[F\left(x_{\left(k\right)}\right)-{\displaystyle \frac{k}{n+1}}\right]}^2\hfill \\ & =\sum _{k=1}^{n+1}{\left[{\displaystyle \frac{{\alpha }^{1-{\left(\frac{1-e^{-\theta x_k}}{1+e^{-\theta x_k}}\right)}^{\alpha }}-\alpha }{1-\alpha }}-{\displaystyle \frac{k}{n+1}}\right]}^2.\hfill \end{array}$

$\begin{array}{cc}\hfill W(\alpha ,\theta )& =\sum _{k=1}^n{\displaystyle \frac{{(n+1)}^2(n+2)}{k(n-k+1)}}{\left[F\left(x_{\left(k\right)}\right)-{\displaystyle \frac{k}{n+1}}\right]}^2\hfill \\ & =\sum _{k=1}^n{\displaystyle \frac{{(n+1)}^2(n+2)}{k(n-k+1)}}{\left[{\displaystyle \frac{{\alpha }^{1-{\left(\frac{1-e^{-\theta x_k}}{1+e^{-\theta x_k}}\right)}^{\alpha }}-\alpha }{1-\alpha }}-{\displaystyle \frac{k}{n+1}}\right]}^2.\hfill \end{array}$

4.5. Anderson–Darling Estimation (${\Delta }_6$)

The Anderson–Darling test was introduced in [17] as an alternative to traditional statistical methods for assessing whether a sample originates from a non-normal distribution. Later, Reference [18] examined the characteristics of the Anderson–Darling estimator (ADE). Based on his findings, the ADE for the NAP-HL model can be obtained by minimizing the Anderson–Darling statistic, denoted as $A(\alpha ,\theta )$, which is given by

$\begin{array}{cc}\hfill A(\alpha ,\theta )& =-n-{\displaystyle \frac{1}{n}}\sum _{k=1}^n(2k-1)\left[lnF\left(x_{\left(k\right)}\right)+lnS\left(x_{(n+1-k)}\right)\right]\hfill \\ & =-n-{\displaystyle \frac{1}{n}}\sum _{k=1}^n(2k-1)\left[ln\left({\displaystyle \frac{{\alpha }^{1-{\left(\frac{1-e^{-\theta x_k}}{1+e^{-\theta x_k}}\right)}^{\alpha }}-\alpha }{1-\alpha }}\right)+ln\left({\displaystyle \frac{1-{\alpha }^{1-{\left(\frac{1-e^{-\theta x_{n+k-1}}}{1+e^{-\theta x_{n+k-1}}}\right)}^{\alpha }}}{1-\alpha }}\right)\right].\hfill \end{array}$

4.6. Right-Tailed Anderson–Darling Estimation (${\Delta }_7$)

The right-tailed Anderson–Darling test, which emphasizes the behavior of the distribution’s right tail, is employed to evaluate the goodness of fit. Using this approach, the parameters $\alpha$ and $\theta$ of the NAP-HL distribution are estimated. The right-tailed Anderson–Darling (AD) test statistic, denoted by $R(\alpha ,\theta )$, is defined as follows:

$\begin{array}{cc}\hfill R(\alpha ,\theta )& ={\displaystyle \frac{n}{2}}-2\sum _{k=1}^{n}F\left(x_{\left(k\right)}\right)-{\displaystyle \frac{1}{n}}\sum _{k=1}^n(2k-1)lnS\left(x_{(n+1-k)}\right)\hfill \\ & ={\displaystyle \frac{n}{2}}-2\sum _{k=1}^n{\displaystyle \frac{{\alpha }^{1-{\left(\frac{1-e^{-\theta x_k}}{1+e^{-\theta x_{\left(k\right)}}}\right)}^{\alpha }}-\alpha }{1-\alpha }}-{\displaystyle \frac{1}{n}}\sum _{k=1}^n(2k-1)ln\left({\displaystyle \frac{1-{\alpha }^{1-{\left(\frac{1-e^{-\theta x_{n+k-1}}}{1+e^{-\theta x_{n+k-1}}}\right)}^{\alpha }}}{1-\alpha }}\right).\hfill \end{array}$

5. Monte Carlo Simulation for Estimator Evaluation

To rigorously assess the performance of several estimation strategies used for the suggested probability distribution, we conduct a comprehensive Monte Carlo simulation study. The primary aim of this simulation is to compare the estimators in terms of their accuracy, efficiency, and robustness across different sample sizes and scenarios. Each sample was analyzed using the seven estimation methods discussed in the previous section. To compare the performance of these methods, we evaluate the absolute bias (AB), mean square error (MSE) and mean relative error (MRE) for each parameter estimate. The following equations are employed to compute these statistics:

(44)$\mathrm{AB}={\displaystyle \frac{1}{n}}\sum _{i=1}^n\left|({\widehat{\theta }}_i-{\theta }_i)\right|,$

(45)$\mathrm{MSE}={\displaystyle \frac{1}{n}}\sum _{i=1}^n{({\widehat{\theta }}_i-{\theta }_i)}^2,$

(46)$\mathrm{MRE}={\displaystyle \frac{1}{n}}\sum _{i=1}^n\left|{\displaystyle \frac{{\widehat{\theta }}_i-{\theta }_i}{{\theta }_i}}\right|.$

The outcomes of the Monte Carlo simulation are compiled in Table 3, Table 4 and Table 5. These findings are pivotal for guiding practitioners toward the most reliable estimator for real-world applications of the proposed model.

Interpretation at the End of the Simulation

A number of inferences can be made from the systematic examination of the simulation findings, such as the following:

The bias of every estimator, regardless of the estimation technique, decreases as the sample size increases. This suggests that larger samples produce estimates that are more accurate and have less systematic error.

6. Data Fitting

In this section, Two real datasets are evaluated to prove the flexibility of the NAP-HL distribution. Test statistics for the NAP-HL distribution and other competitive distributions are calculated. The NAP-HL distribution is compared with other distributions, namely, the odd Frechet half-logistic (OFHL) distribution [19], the Kumaraswamy half-logistic (KHL) distribution [20], the exponentiated half-logistic (EHL) distribution [21], the Marshall–Olkin half-logistic (MoHL) distribution [22], the half-logistic (HL) distribution [23], and the power half-logistic (PoHL) distribution [24].

For clarity and completeness, the analytical expressions of the probability density functions (PDFs) of the competing models are presented below:

The odd Frechet half-logistic (OFHL) distribution’s PDF is given as

(47)$f(x;\alpha ,\gamma )={\displaystyle \frac{\alpha \gamma {\left(2e^{-\gamma x}\right)}^{\alpha }}{{\left(1-e^{-\gamma x}\right)}^{\alpha +1}}}exp\left\{-{\left({\displaystyle \frac{2e^{-\gamma x}}{1-e^{-\gamma x}}}\right)}^{\alpha }\right\}$

6.1. Application in Metrology

A set of 20 component failure times, known as the SDS dataset, was analyzed in [25] using the Pareto distribution and Bayesian prediction techniques. The observed failure times are as follows: 0.0009, 0.0040, 0.0142, 0.0221, 0.0261, 0.0418, 0.0473, 0.0834, 0.1091, 0.1252, 0.1404, 0.1498, 0.1750, 0.2031, 0.2099, 0.2168, 0.2918, 0.3465, 0.4035, and 0.6143. These values represent the time-to-failure measurements collected in ascending order and exhibited right-skewed behavior, which may suggest increasing or bathtub-shaped hazard rates. The authors modeled the dataset using the Pareto distribution and employed a Bayesian prediction function to make inferences about component reliability and future failure behavior.

6.2. Application in Engineering

The data represent the fatigue fracture life of Kevlar 373/epoxy subjected to constant pressure at the 90-stress level until all specimens failed. This dataset includes seventy-six observations and was analyzed in [26]. The observations are as follows: 0.0251, 0.0886, 0.0891, 0.2501, 0.3113, 0.3451, 0.4763, 0.5650, 0.5671, 0.6566, 0.6748, 0.6751, 0.6753, 0.7696, 0.8375, 0.8391, 0.8425, 0.8645, 0.8851, 0.9113, 0.9120, 0.9836, 1.0483, 1.0596, 1.0773, 1.1733, 1.2570, 1.2766, 1.2985, 1.3211, 1.3503, 1.3551, 1.4595, 1.4880, 1.5728, 1.5733, 1.7083, 1.7263, 1.7460, 1.7630, 1.7746, 1.8275, 1.8375, 1.8503, 1.8808, 1.8878, 1.8881, 1.9316, 1.9558, 2.0048, 2.0408, 2.0903, 2.1093, 2.1330, 2.2100, 2.2460, 2.2878, 2.3203, 2.3470, 2.3513, 2.4951, 2.5260, 2.9911, 3.0256, 3.2678, 3.4045, 3.4846, 3.7433, 3.7455, 3.9143, 4.8073, 5.4005, 5.4435, 5.5295, 6.5541, 9.0960.

The descriptive properties of the metrology and engineering data are summarized in Table 6 and Table 7. Table 6 summarizes the metrology dataset, which contains 20 observations with values ranging from 0.0009 to 0.6143. The mean and standard deviation are 0.16126 and 0.15733, respectively, indicating moderate dispersion. Table 7, on the other hand, details the engineering dataset of 76 observations, showing a much wider range (0.0251 to 9.0960) and higher average (mean = 1.9592, SD = 1.5740), reflecting greater variability.

6.3. Evaluation Criterion

This section presents the application of the NAP-HL distribution to two real-life datasets. The unknown parameters of the NAP-HL distribution are estimated using the maximum likelihood estimation (MLE) method. To assess the goodness of fit and compare the performance of the model, several evaluation criteria are employed. These include the maximized log-likelihood value ($\widehat{\ell }$), Anderson–Darling statistic ($A^{*}$), Cramér–von Mises statistic ($W^{*}$) and Kolmogorov–Smirnov statistic (K-S) along with its associated p-value. Additionally, information criteria such as the Akaike information criterion (AIC) and Bayesian information criterion (BIC) are used for model comparison. All computations are performed using the R software version 4.3.2 and the results are reported in Table 8 and Table 9. Furthermore, we fitted the NAP-HL distribution by utilizing seven estimation procedures and the results are reported in Table 10 and Table 11.

The estimated PDF, P–P plots, Q–Q plots, survival function (SF), TTT plots and box plots of the NAP-HL model for the two datasets are contrasted in Figure 3 and Figure 4, respectively.

6.4. Results and Discussion

Box plots are a standard way to represent the summary statistics of a data distribution. In Figure 3 and Figure 4, the box plots for dataset 1 and dataset 2 are presented. Both datasets are right-skewed with some outliers, highlighting the extreme behavior in the data distributions.

Table 8 and Table 9 report the values of the maximized log-likelihood ($\widehat{\ell }$), AIC, BIC, Anderson–Darling ($A^{*}$), Cramér–von Mises ($W^{*}$), and Kolmogorov–Smirnov (K-S) statistics and the corresponding p-values for both the datasets, respectively.

The distribution with the smallest values of all the information criteria and the largest p-value is typically considered the best fit. Based on these criteria, the superiority of the NAP-HL model over the competing models is evident.

For a more comprehensive graphical representation, several parametric and non-parametric plots are provided in Figure 3 and Figure 4. These include the fitted PDF, probability–probability (P–P) plots, quantile–quantile (Q–Q) plots, survival function (SF), total time on test (TTT) plots, and box plots of the NAP-HL distribution for each dataset. The figures demonstrate that the NAP-HL distribution fits both the datasets very well.

The failure rate of application 1 is bathtub-shaped because the TTT-transform plot displayed in Figure 3 is initially convex below the 45° line and then concave above the 45° line and the box plot has few outliers, as shown in Figure 3.

The TTT-transform plot of application 2 shows a concave pattern above the 45° line, providing insight into the shape of the hazard function, as shown in Figure 2 and reveals the presence of outliers in the box plot illustrated in Figure 4.

7. Concluding Remarks

Continuous data in many disciplines demand more flexible lifetime models than those offered by the classical half-logistic law. We introduce the NAP-HL (novel alpha-power half-logistic) distribution, a three-parameter extension that embeds a shape control into the standard half-logistic form. By adjusting this shape parameter, the NAP-HL model can produce increasing, decreasing, or bathtub-shaped hazard rates, thus capturing a wide range of real-world aging and failure behaviors.

We derive closed-form expressions for the main characteristics of the NAP-HL model—moments, quantile function, and hazard function—highlighting how the added flexibility emerges from the exponentiation mechanism. A comprehensive Monte Carlo study compares seven estimation methods revealing their relative performance under different sample sizes and true parameter settings.

To assess empirical usefulness, we fit the NAP-HL model to two benchmark datasets: a metrology and an engineering dataset. In every case, the NAP-HL model achieves lower AIC and BIC and superior goodness-of-fit statistics (AD, CvM, K-S) than its half-logistic precursor and several competing families.

Future work will extend the NAP-HL model into regression frameworks, accommodate censored and truncated data streams, explore Bayesian estimation for small samples, and integrate with machine learning pipelines for large-scale predictive analytics. Such enhancements promise to make the NAP-HL model a go-to model for complex reliability and survival analysis tasks.

Footnotes

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Figure 1 PDF curves of the NAP-HL model for different parameter settings of $\alpha$ and $\theta$.

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Figure 2 Diverse hazard rate shapes of the NAP-HL model for different settings of $\alpha$ and $\theta$.

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Figure 3 Comparative plots for evaluating the adequacy of the NAP-HL model using metrology data.

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Figure 4 Comparative plots for evaluating the adequacy of the NAP-HL model using engineering data.

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