1. Introduction

There are various probability distributions with support on (0,1). One of the most used is the $Beta$ distribution, which is a family of continuous probability distributions defined in the interval (0,1) with two shape parameters, both positive, normally denoted by $\alpha$ and $\beta$.

In Bayesian inference, the $Beta$ distribution is generally used as the conjugate prior to probability distribution for the Bernoulli, binomial, negative binomial, and geometric distributions. For example, the $Beta$ distribution can be used in Bayesian analysis to describe any initial knowledge about the probability of success. In addition, it is a density that is usually used to model the data associated with percentages and proportions.

The usual formulation of the $Beta$ distribution is also known as the type I $Beta$ distribution, whose density function is provided by:

(1)$\begin{array}{c}\hfill f_X\left(x\right)=\frac{\Gamma (\alpha +\beta )}{\Gamma \left(\alpha \right)\Gamma \left(\beta \right)}{x}^{\alpha -1}{(1-x)}^{\beta -1},\end{array}$

A distribution similar to $Beta$ is the Kumaraswamy distribution [1], but it is simpler in the sense that simulations can be obtained from the inverse of the cumulative distribution, since it has a closed expression, alike the quantiles. Its density is defined by:

(2)$\begin{array}{c}\hfill f_X\left(x\right)=\alpha \beta x^{\alpha -1}{(1-x^{\alpha })}^{\beta -1},\end{array}$

Mazucheli et al. [2] show the Unitary Weibull distribution where they present some inferential procedures. Mazucheli et al. [3] present a unitary version of the Weibull distribution as an alternative to the $KW$ distribution to model quantiles conditional on covariates. The stochastic representation of a Unitary Weibull distribution is provided by $V=e^{-X}$, with $X\sim Weibull(\alpha ,\beta )$, denoted by $V\sim UW(\alpha ,\beta )$, which has a density function provided by:

(3)$\begin{array}{c}\hfill f_V\left(v\right)=\frac{1}{v}\alpha \beta {[-log\left(v\right)]}^{\beta -1}exp\left\{-\alpha {[-log\left(v\right)]}^{\beta }\right\},0<v<1.\end{array}$

The article is organized in the following manner. In Section 2, we provide the stochastic representation, the pdf of a random variable with $GUW$ distribution, and present some properties and the distribution $UW2$ as a particular case. The cumulative distribution function (cdf), quantiles, reliability functions, and hazard rate, moments, skewness coefficients, and kurtosis are also provided. Some statistical properties are provided. The Canonical Unitary Weibull distribution and its properties are presented. In Section 3, an inference is made through a simulation study of the parameter estimates using the maximum likelihood method. In addition, the $Beta$, $KW$, $UW$, and $UW2$ distributions are fitted to real data sets in Section 4. In Section 5, a discussion and the main conclusions are presented.

2. The Generalized Unitary Weibull Family of Distribution

A random variable Y has a Generalized Unitary Weibull distribution, of parameters ${\theta }_1$, ${\theta }_2$, $\alpha$, and $\beta >0$, denoted by $Y\sim GUW({\theta }_1,{\theta }_2,\alpha ,\beta )$, if its stochastic representation is provided by:

(4)$Y=\frac{X_1}{X_1+X_2},$

2.1. Density Function

Now, we provide some elementary properties.

2.2. Density Function of the Unitary Weibull Distribution Type 2

Figure 1 below show each pdf of the $UW2$ distribution compared to the $Beta$ distribution. It shows that, for certain values of the parameters, respectively, the distributions are very similar and in others there is quite a difference.

Figure 2 shows the pdfs of the $UW2$ distribution for $\beta =2$ and different values of $\theta$.

In Figure 3, we graphically illustrate the behavior of the Cumulative distribution function of the $UW2$ distribution for different values of $\theta$ and $\beta =2$.

2.3. The Reliability, Hazard Rate Functions and Increasing Failure Rate

Two important measures of reliability are the reliability function and hazard (failure) rate function. The reliability function of a random variable Y is defined by $S_Y\left(t\right)=1-F_Y\left(t\right)$, where $F_Y$ denotes the cdf of Y. The risk rate function is defined by $h_Y\left(t\right)=f_Y\left(t\right)/(1-F_Y\left(t\right))$. For the distribution $UW2$, as a direct consequence of Proposition 3, both reliability measures can be expressed in closed form. The corresponding expression is obtained in the following Proposition simple form.

In Table 1, it can be seen that the $UW2$ distribution better captures the values’ outliers compared to the $UW$, $KW$, and $\beta$ distributions, since the reliability is higher.

Figure 4 shows the hazard rate function of the $UW2$ distribution for different values of $\theta$ and $\beta =2$. Looking at the graphical representation, it is clear that it presents a wide variety of forms. Therefore, the new family of distributions is flexible enough to model real data sets.

Next, we present the Increasing Failure Rate, which is defined as the derivative of the failure rate function provided in (15).

2.4. Moments

The following statement shows the moments for the $UW2$ distribution. Essentially, these moments are expressed as a numerical integral (the problem of obtaining a closed analytic expression remains open).

In particular, for $r=1$ we have:

(20)$\begin{array}{ccc}\hfill {\mu }_1(\theta ,\beta )& =& 1-{\mu }_1\left(\theta ,\frac{1}{\beta }\right).\hfill \end{array}$

Figure 5 and Table 2 graphically and numerically show the behavior of the asymmetry and kurtosis coefficients of the $UW2$ distribution and are consistent with what is represented in corollary 2. That is, the value of the asymmetry coefficient, given a value of the parameter $\theta$, is the same for $\beta$ as for $1/\beta$, but with the opposite sign. For example: ${\beta }_1(5,1/2)=-0.4592$ and ${\beta }_1(5,2)=0.4592$. Similarly, the value of the kurtosis coefficient, given a value of the parameter $\theta$, is the same for $\beta$ as it is for $1/\beta$. For example: ${\beta }_2(5,1/2)={\beta }_2(5,2)=4.6954$.

2.5. Some Statistical Properties

2.5.1. Entropy of $UW2$

The entropy $H(\Theta )$ can be obtained using the density function of Y; specifically, the following form expression is obtained:

(25)$\begin{array}{c}\hfill H(\Theta )=-{\int }_0^1{f}_Y(y,\Theta )ln\left(f_Y(y,\Theta )\right)dy.\end{array}$

(26)$\begin{array}{c}\hfill H(\theta ,\beta )=-{\int }_0^1\frac{\theta {\beta }^{\theta }{y}^{\theta }{(1-y)}^{\theta -1}}{{\left({\left(\beta y\right)}^{\theta }+{\left(1-y\right)}^{\theta }\right)}^2}ln\left(\frac{\theta {\beta }^{\theta }{y}^{\theta }{(1-y)}^{\theta -1}}{{\left({\left(\beta y\right)}^{\theta }+{\left(1-y\right)}^{\theta }\right)}^2}\right)dy.\end{array}$

Table 3 shows the entropy values of the $UW2$ distribution for different values of the parameters $\theta$ and $\beta$.

2.5.2. Mean Residual Life

An important reliability quantity for positive random variables is the mean residual life, which is defined as $\mu (t;\theta ,\beta )=\frac{1}{1-F_Y\left(t\right)}{\int }_t^{\infty }(1-F_Y\left(y\right))dy,$$t>0$.

For the case that $Y\sim UW2(\theta ,\beta )$, then the mean residual life of Y is obtained by replacing:

(27)$\begin{array}{ccc}\hfill F_Y\left(t\right)& =& {\left(1+{\left(\frac{1-y}{\beta y}\right)}^{\theta }\right)}^{-1},t>0.\hfill \end{array}$

2.5.3. Incomplete Moments

The r-th incomplete moment of $Y\sim f(y;\Theta )$ is defined as:

(28)$\begin{array}{ccc}\hfill m_r(y;\Theta )& =& {\int }_0^y{t}^{r}f(t;\Theta )dt.\hfill \end{array}$

If $Y\sim UW2(\theta ,\beta )$, then the r-th incomplete moment of Y is provided by:

(29)$m_r(y;\theta ,\beta )={\int }_0^y\frac{t^{\theta +r-1}{(1-t)}^{\theta -1}}{{[{\left(\beta t\right)}^{\theta }+{(1-t)}^{\theta }]}^2}dt,0<y<1.$

An interesting application of the first incomplete moment is that the mean deviation about the mean $\mu$ of Y can be directly obtained, specifically by means of the relation (see [4]):

(30)$\begin{array}{ccc}\hfill E\left(|Y-\mu |\right)& =& 2\mu F(\mu ;\theta ,\beta )-2m_1(\mu ;\theta ,\beta ),\hfill \end{array}$

2.5.4. Lorenz Curve and the Gini Index

The Lorentz curve and Gini coefficient are tools used in the field of economics to measure income inequality in a society.

The Lorenz curve (see [5]), $L(x;\Theta )$, can also be obtained from the quantile function of Y; specifically, the following closed-form expression is obtained:

(31)$\begin{array}{c}\hfill L\left(p,\Theta \right)=\frac{1}{{\mu }_1}{\int }_0^p{F}^{-1}\left(y\right)dy,0<p<1,\end{array}$

If $Y\sim UW2(\theta ,\beta )$. Next, the Lorenz curve is provided by:

(32)$\begin{array}{c}\hfill L\left(p,\theta ,\beta \right)=\frac{1}{{\mu }_1}{\int }_0^p{\left[1+\beta {\left(\frac{1}{y}-1\right)}^{\frac{1}{\theta }}\right]}^{-1}dy,0<p<1,\end{array}$

The Gini index (see [5]) is the measure of inequality associated with the Lorenz curve. For the random variable X, the Gini index is defined by:

(33)$\begin{array}{c}\hfill G(\alpha ,\theta )=1-\frac{1}{\mu }{\int }_0^{\infty }{(1-F(y;\alpha ,\theta ))}^{2}dy.\end{array}$

In the next result, an analytical expression is provided for $G(\alpha ,\theta )$.

Figure 6 shows the Lorenz curve using the $UW2$ distribution for different values of the parameters $\theta$ and $\beta$.

It can be observed that, as $\theta$ increases, inequality with the Gini index decreases, and, as $\beta$ increases, inequality with the Gini index increases.

2.6. Canonical Type 2 Unitary Weibull Distribution

Let $Y\sim UW2(\theta ,\beta )$ causing $\theta =1$; then, the distribution of Y is called the canonical type 2 Weibull distribution and we will denote it by $Y\sim UW2(1,\beta )$ and its density function has the following expression:

(35)$\begin{array}{c}\hfill f_Y\left(y\right)=\frac{\beta }{{\left(1-\left(1-\beta \right)y\right)}^2},0<y<1.\end{array}$

Its most important properties are:

• 1.. The $cdf$ of Y is provided by:

  (36)$\begin{array}{c}\hfill F_Y\left(t\right)=\frac{\beta t}{1+\left(\beta -1\right)t^{}},0<t<1.\end{array}$

• 2.. Quantile function of Y is:

  (37)$t=\frac{p\left(1-\beta \right)+\beta }{p}.$

• 3.. The r-th moment of Y has the following expression:

  (38)$\begin{array}{ccc}\hfill {\mu }_r& =& E\left[Y^r\right]=1-r\beta {}_2{F}_1\left(1,r+1;r+2;-(\beta -1)\right)\Gamma \left(r+1\right),,r=1,2,\dots \hfill \end{array}$

  where ${}_2{F}_1\left(a,b;c;-z\right)=\frac{1}{B(b,c-b)}{\int }_0^1\frac{x^{b-1}{(1-x)}^{c-b-1}}{{\left(1+zx\right)}^a}dx$.

  In particular, for $r=1,2,3,4$ we have:

  (39)$\begin{array}{ccc}\hfill {\mu }_1& =& \frac{\beta ln\left(\beta \right)+1-\beta }{{\left(\beta -1\right)}^2};\beta \ne 1\hfill \end{array}$

  (40)$\begin{array}{ccc}\hfill {\mu }_2& =& \frac{{\beta }^2-2\beta ln\left(\beta \right)-1}{{\left(\beta -1\right)}^3};\beta \ne 1\hfill \end{array}$

  (41)$\begin{array}{ccc}\hfill {\mu }_3& =& \frac{{\beta }^3-6{\beta }^2+3\beta +6\beta ln\left(\beta \right)+2}{2{\left(\beta -1\right)}^4};\beta \ne 1\hfill \end{array}$

  (42)$\begin{array}{ccc}\hfill {\mu }_4& =& \frac{{\beta }^4-6{\beta }^3+18{\beta }^2-10\beta -12\beta ln\left(\beta \right)-3}{3{\left(\beta -1\right)}^5};\beta \ne 1,\hfill \end{array}$

• 4.. Kurtosis coefficient is provided by following expression.

  (43)$\begin{array}{ccc}\hfill {\beta }_2& =& \frac{6{\left(\beta -1\right)}^3\left({\beta }^4-6{\beta }^3+18{\beta }^2-10\beta -12\beta ln\left(\beta \right)-3\right)-4{\left(\beta -1\right)}^2\left(\beta ln\left(\beta \right)+1-\beta \right)\left({\beta }^3-6{\beta }^2+3\beta +6\beta ln\left(\beta \right)+2\right)}{{\left({\left(\beta -1\right)}^5\left({\beta }^2-2\beta ln\left(\beta \right)-1\right)-{\left(\beta ln\left(\beta \right)+1-\beta \right)}^2\right)}^2}\hfill \\ & +& \frac{6\left(\beta -1\right){\left(\beta ln\left(\beta \right)+1-\beta \right)}^2\left({\beta }^2-2\beta ln\left(\beta \right)-1\right)-3{\left(\beta ln\left(\beta \right)+1-\beta \right)}^4}{{\left({\left(\beta -1\right)}^5\left({\beta }^2-2\beta ln\left(\beta \right)-1\right)-{\left(\beta ln\left(\beta \right)+1-\beta \right)}^2\right)}^2}\hfill \end{array}$

  Figure 7 shows the graphic behavior of the kurtosis for the canonical distribution $UW2$ for different values of $\beta$.

• 5.. The Lorenz curve of Y is:

  (44)$\begin{array}{ccc}\hfill L\left(p,1,\beta \right)& =& \frac{p-p\beta -\beta (ln\left(\left|(p-1)\beta -p\right|\right)+\beta ln\left(\left|-\beta \right|\right)}{\beta ln\beta -\beta +1}.\hfill \end{array}$

• 6.. The expression for the Gini index of Y is provided by:

  (45)$\begin{array}{ccc}\hfill G\left(1,\beta \right)& =& \frac{\beta \left[\left(1+\beta \right)ln\left(\beta \right)-2\left(\beta -1\right)\right]}{\left(\beta -1\right)\left[1-\beta \left(1-ln\left(\beta \right)\right)\right]}.\hfill \end{array}$

  Figure 8 shows the Lorenz curve and the Gini index of the canonical $UW2$ distribution for different values of $\beta$ in which the parameter $\beta$ is directly proportional to the Gini index.

• 7.. Entropy of Y:

  (46)$\begin{array}{c}\hfill H(1,\beta )=2-\frac{\beta +1}{\beta -1}ln\left(\beta \right).\end{array}$

  Figure 9 shows the graph of the entropy of the canonical $UW2$ distribution for different values of $\beta$.

3. Inference

In this section, we discuss the statistical inference of the estimators for the model $Y\sim UW2(\theta ,\beta )$.

3.1. Maximum Likelihood Estimate

We now discuss the maximum likelihood estimate. Given a random sample $Y_1,\dots ,Y_n$ of the distribution $UW2\left(\theta ,\beta \right)$, the logarithm of the likelihood function can be written as:

(47)$l(\theta ,\beta )=nln\theta +n\theta ln\beta +(\theta -1)\sum _{i=1}^{n}ln{y}_i+(\theta -1)\sum _{i=1}^{n}ln(1-y_i)-2\sum _{i=1}^{n}ln[{\left(\beta y_i\right)}^{\theta }+{(1-y_i)}^{\theta }].$

(48)$\begin{array}{ccc}\hfill \sum _{i=1}^n\frac{y_i^{\theta -1}}{{\left(\beta y_i\right)}^{\theta }+{(1-y_i)}^{\theta }}& =& \frac{n}{2{\beta }^{\theta +1}}\hfill \end{array}$

(49)$\begin{array}{ccc}\hfill 2\sum _{i=1}^n\frac{{\left(\beta y_i\right)}^{\theta }ln\left(\beta y_i\right)+{(1-y_i)}^{\theta }ln(1-y_i)}{{\left(\beta y_i\right)}^{\theta }+{(1-y_i)}^{\theta }}-\frac{ln{y}_i(1-y_i)}{2}& =& \frac{n}{\theta }+nln\beta .\hfill \end{array}$

The solutions to the equations can be obtained using numerical procedures such as the Newton–Raphson procedure.

3.2. Simulation Study

We use the Monte Carlo method to generate random numbers from the distribution $UW2(\theta ,\beta )$.

Table 4 presents a simulation study of 1000 samples of size $n=50,100$, and 200 for different values of the parameters $\theta$ and $\beta$. These random values are obtained from $u_i\sim U(0,1),i=1,2,...,n$, and substituting in the quantile $y_i=\left[1+\beta {\left(\frac{1}{u_i}-1\right)}^{\frac{1}{\theta }}\right]$ for given $\theta$ and $\beta$, we obtain the random values of the distribution $UW2(\theta ,\beta )$. On the other hand, the table shows that when the sample size increases, the parameter estimates converge asymptotically to the parameters. However, the standard deviations and the average length of the confidence intervals decrease as the sample size increases. This allows us to verify the consistency of the parameter estimates. Finally, the values obtained from the empirical coverage are as expected, since it is close to a 95% confidence.

4. Analysis of Real Data

4.1. Example 1: Application to Medical Data

In this example, we compute the MLEs of $(\beta ,\alpha ,\theta )$ to fit the $KW$, $Beta$, $UW$, and $UW2$ models to a real data set. The data can be found in the book on Biostatistics (see [6] Daniel, Pag. 475) and correspond to a study carried out by Slemenda et al. [7], in which he investigates the effects of lateral bone mineral density (LBMD) on spinal osteoarthritis in 66 women aged 34–87 years. Some descriptive statistics are shown in Table 5. Table 6 shows the MLEs for the models: $KW$, $Beta$, $UW$, and $UW2$. Using the Akaike criterion (AIC) [8], criterion Bayesian (BIC) [9], the Kolmogorov–Smirnov (KS) test, and Chen’s approximate goodness-of-fit test [10] (W*), (A*), we see that model $UW2$ best fits the data. The advantage of the $UW2$ model is more evident for the data with more extreme observations, see Figure 10 (side right). Figure 11 and Figure 12 show that the $UW2$ distribution fits the data better than the $UW$, $Beta$, and $KW$ distributions.

Observing Table 6, we see that the values of AIC and BIC are lower than those of their competitors, thus the statistic $KS$, A*, and W* indicating the best fit of the distribution $UW2$ in comparison with the distributions $KW$, $Beta$, and $UW$.

4.2. Example 2: An Application to Environment Data

In this section, we compute the MLEs of $(\alpha ,\beta ,\theta )$ to fit the $Beta$, $KW$, $UW$, and $UW2$ models to a real environment data set. The data can be found at https://dga.mop.gob.cl/servicioshidrometeorologicos/Paginas/default.aspx (1 December 2022) servicioshidrometeorologicos/Paginas/default.aspx and they correspond to the fluviometric and meteorological data recorded in monitoring stations from Arica to Tierra del Fuego. In addition, you will have access to various official statistical reports on hydrometeorological variables and water quality, obtained from our National Hydrometric Network; the analyzed data are the percentage of dissolved oxygen in a lake. Some descriptive statistics are shown in Table 7. Table 8 shows the MLEs for the models: $Beta$, $KW$, $UW$, and $UW2$. From the Akaike criteria (AIC), (BIC), we see that the $UW2$ model best fits the data. Figure 13 shows that the $UW2$ model fits the data better than $UW$, $Beta$, and $KW$ models.

The QQ plots of the data with the $UW2$ distribution compared to the $Beta$, $KW$, and $UW2$ distributions adjusted with the maximum likelihood estimators of their parameters are shown in Figure 14.

4.3. Example 3: An Application to Quantile Regression

4.3.1. One-Dimensional Quantile Regression

Translating this concept of quantile to the regression line, we obtain the linear quantile regression (see [11]). If we assume that:

(50)$\begin{array}{ccc}\hfill Y_i& =& {\alpha }_{0,\tau }+{\alpha }_{1,\tau }{X}_i+{ϵ}_{i,\tau },\forall iϵ(1,...,n),\hfill \end{array}$

(51)$\begin{array}{ccc}\hfill Q_{\tau }\left(Y_i\right|X)& =& {\alpha }_{0,\tau }+{\alpha }_{1,\tau }{X}_i.\hfill \end{array}$

(52)${\widehat{\alpha }}_{\tau }=arg\underset{{\alpha }_{\tau }ϵ{\Re }^2}{min}\left(\sum _{Y_i\ge A}\tau |Y_i-{\alpha }_{0,\tau }-{\alpha }_{1,\tau }{X}_i|+\sum _{Y_i<A}(1-\tau )|Y_i-{\alpha }_{0,\tau }-{\alpha }_{1,\tau }{X}_i|\right),$

4.3.2. Quantile Regression Unitary Weibull Type 2

In this case, in the regression equation:

(53)$\begin{array}{ccc}\hfill Y_i& =& {\alpha }_{0,\tau }+{\alpha }_{1,\tau }{X}_i+{ϵ}_{i,\tau },\forall iϵ(1,...,n),\hfill \end{array}$

Let ${\mu }_{\tau }={\left[1+\beta {\left(\frac{1}{\tau }-1\right)}^{\frac{1}{\theta }}\right]}^{-1}$, then $\beta =\left({\displaystyle \frac{1-{\mu }_{\tau }}{{\mu }_{\tau }}}\right){\left({\displaystyle \frac{\tau }{1-\tau }}\right)}^{1/\theta }$ and substituting into the density function of Y, we obtain:

(54)$\begin{array}{c}\hfill f_Y\left(y\right)=\frac{\theta {\left({\displaystyle \frac{1-{\mu }_{\tau }}{{\mu }_{\tau }}}\right)}^{\theta }\left({\displaystyle \frac{\tau }{1-\tau }}\right)y^{\theta -1}{(1-y)}^{\theta -1}}{{\left[{\left({\displaystyle \frac{1-{\mu }_{\tau }}{{\mu }_{\tau }}}\right)}^{\theta }\left({\displaystyle \frac{\tau }{1-\tau }}\right)y^{\theta }+{(1-y)}^{\theta }\right]}^2},0<y<1,\end{array}$

(55)$\begin{array}{c}\hfill F_Y\left(y\right)={\left[1+\frac{{\left(\frac{1-\tau }{\tau }\right)}^{\theta +1}}{\frac{1-{\mu }_{\tau }}{{\mu }_{\tau }}}\right]}^{-1}.\end{array}$

4.3.3. An Application of Quantile Regression to Praters Gas Mileage Data

To illustrate this, we consider Simas et al. [12] investigating Praters gas mileage data based on the same mean equation as above, but now with temperature. Table 9 shows the statistics of these data. Table 10 shows the maximum likelihood estimators as predictor variables of $({\alpha }_0,{\alpha }_1)$ and their standard errors for the $UW2$, $UW$, and $Beta$ distributions.

Looking at Table 11 and Figure 15 and Figure 16, we see that the $UW2$ distribution compared to the $Beta$ and $UW$ distributions fits better using quantile regression when the variable response has high kurtosis.

5. Discussion

In this work, we have introduced a new family of distributions with a domain in the interval (0,1) and with heavier tails than some similar distributions seen in the literature. The new family is based on a transformation of two independent random variables with a two-parameter Weibull distribution. We define the new family by its stochastic representation. We provide its density function and reliability function and also provide some statistical properties of interest. In the inferential part, we estimate the parameters of the new model using the maximum likelihood method and the information criteria are used to select the best model and evaluate the goodness of fit of the new distribution compared to other similar distributions. A Monte Carlo simulation study was carried out to empirically evaluate the statistical performance of the estimators, using the maximum likelihood method for the parameters of the new model. In addition, we show the coverage probabilities and the mean length of the confidence intervals obtained for the corresponding parameters using the asymptotic normality of these estimators. The simulation study reported consistent performance of these estimators. Finally, three illustrations with real data were created, with two related to medical information and the environment. A third application was related to quantile regression. These analyses provided sufficient information to conclude that the proposed model presents better behavior when compared to others from the competition.

Footnotes

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Figure 1. [Forumla omitted. See PDF.] pdf for [Forumla omitted. See PDF.] and different values of [Forumla omitted. See PDF.].

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Figure 2. [Forumla omitted. See PDF.] pdf for [Forumla omitted. See PDF.] and different values of [Forumla omitted. See PDF.].

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Figure 3. Cdf of [Forumla omitted. See PDF.] for different values [Forumla omitted. See PDF.] and [Forumla omitted. See PDF.].

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Figure 4. The hazard rate functions for the [Forumla omitted. See PDF.] distribution.

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Figure 5. Plots of the skewness (left) and kurtosis of the [Forumla omitted. See PDF.] distribution (right).

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Figure 6. [Forumla omitted. See PDF.] Lorenz Curve for different values of [Forumla omitted. See PDF.] and [Forumla omitted. See PDF.].

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Figure 7. [Forumla omitted. See PDF.] canonical kurtosis for different values of [Forumla omitted. See PDF.].

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Figure 8. Lorenz curve and Gini index of the canonical [Forumla omitted. See PDF.] distribution for different values of [Forumla omitted. See PDF.].

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Figure 9. Graph of the entropy of the canonical [Forumla omitted. See PDF.] distribution for different values of [Forumla omitted. See PDF.].

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Figure 10. Histogram for LBMD data with Densities [Forumla omitted. See PDF.] (solid line), [Forumla omitted. See PDF.] (dashed line), [Forumla omitted. See PDF.] (dotted line), and [Forumla omitted. See PDF.] (dashed dotted line) (left) and tails (right).

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Figure 11. QQ plots for the LBMD data set: [Forumla omitted. See PDF.] (a), [Forumla omitted. See PDF.] (b), [Forumla omitted. See PDF.] (c), and [Forumla omitted. See PDF.] (d).

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Figure 12. Comparison of cumulative distributions for the LBMD data set for [Forumla omitted. See PDF.] (blue line), [Forumla omitted. See PDF.] (red line), [Forumla omitted. See PDF.] (green line), and [Forumla omitted. See PDF.] (orange line).

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Figure 13. Histogram for percent dissolved oxygen data (left) with densities of [Forumla omitted. See PDF.] (solid line), [Forumla omitted. See PDF.] (dashed line), [Forumla omitted. See PDF.] (dotted line), and [Forumla omitted. See PDF.] (dashed line) and tails (right).

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Figure 14. QQ plots for the data set: [Forumla omitted. See PDF.] (a), [Forumla omitted. See PDF.] (b), [Forumla omitted. See PDF.] (c), and [Forumla omitted. See PDF.] (d).

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Figure 15. Quantile regression for Yield and Temperature data with [Forumla omitted. See PDF.] density (left) and [Forumla omitted. See PDF.] density (right).

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Figure 16. Quantile regression for Yield and Temperature data with [Forumla omitted. See PDF.] density (left) and [Forumla omitted. See PDF.] density (right).