TOPP-LEONE DISTRIBUTION

Phitter implementation

Distribution Definition

import phitter

distribution = phitter.continuous.ToppLeone({"alpha": *, "min": *, "max": *})

💡 The distribution's parameters are defined equation section below

Distribution Methods and Attributes

## CDF, PDF, PPF receive float or numpy.ndarray.
distribution.cdf(float | numpy.ndarray) # -> float | numpy.ndarray
distribution.pdf(float | numpy.ndarray) # -> float | numpy.ndarray
distribution.ppf(float | numpy.ndarray) # -> float | numpy.ndarray
distribution.sample(int) # -> numpy.ndarray

## STATS
distribution.mean # -> float
distribution.variance # -> float
distribution.standard_deviation # -> float
distribution.skewness # -> float
distribution.kurtosis # -> float
distribution.median # -> float
distribution.mode # -> float

Equations

Distribution Definition

$$X\sim \mathrm{ToppLeone}(\alpha ,\text{min},\text{max})$$

Distribution Domain

$$x\in (\text{min},\text{max})$$

Parameters Domain and Constraints

$$\alpha \in {\mathbb{R}}^{+},\text{min}\in \mathbb{R},\text{max}\in \mathbb{R}$$

Cumulative Distribution Function

$$F_X\left(x\right)={[z(x)(2-z(x))]}^{\alpha }$$

Probability Density Function

$$f_X\left(x\right)=\frac{2\alpha }{\text{max}-\text{min}}(1-z(x)){[z(x)(2-z(x))]}^{\alpha -1}$$

Percent Point Function / Sample

$$F_X^{-1}\left(u\right)=\text{min}+(\text{max}-\text{min})(1-\sqrt{1-u^{1/\alpha }})$$

Parametric Centered Moments

$${\tilde{\mu }}_k^{\prime }=E[{\tilde{X}}^k]=\sum _{i=0}^k(\genfrac{}{}{0ex}{}{k}{i}){(-1)}^i\alpha \text{Beta}(\alpha ,1+\frac{i}{2})$$

Parametric Mean

$$\mathrm{Mean}(X)=\text{min}+(\text{max}-\text{min})\times {\tilde{\mu }}_1^{\prime }$$

Parametric Variance

$$\mathrm{Variance}(X)={(\text{max}-\text{min})}^2({\tilde{\mu }}_2^{\prime }-{\tilde{\mu }}_1^{\prime 2})$$

Parametric Skewness

$$\mathrm{Skewness}(X)=\frac{{\tilde{\mu }}_3^{\prime }-3{\tilde{\mu }}_2^{\prime }{\tilde{\mu }}_1^{\prime }+2{\tilde{\mu }}_1^{\prime 3}}{({\tilde{\mu }}_2^{\prime }-{\tilde{\mu }}_1^{\prime 2}{)}^{1.5}}$$

Parametric Kurtosis

$$\mathrm{Kurtosis}(X)=\frac{{\tilde{\mu }}_4^{\prime }-4{\tilde{\mu }}_1^{\prime }{\tilde{\mu }}_3^{\prime }+6{\tilde{\mu }}_1^{\prime 2}{\tilde{\mu }}_2^{\prime }-3{\tilde{\mu }}_1^{\prime 4}}{({\tilde{\mu }}_2^{\prime }-{\tilde{\mu }}_1^{\prime 2}{)}^2}$$

Parametric Median

$$\mathrm{Median}(X)=\text{min}+(\text{max}-\text{min})(1-\sqrt{1-{0.5}^{1/\alpha }})$$

Parametric Mode

$$\mathrm{Mode}(X)=\text{min}+(\text{max}-\text{min})(1-\sqrt{\frac{\alpha -1}{2\alpha -1}})$$

Additional Information and Definitions

• $\tilde{X}\sim \mathrm{ToppLeone}(\alpha ,0,1)$
• $z\left(x\right)=(x-\text{min})/(\text{max}-\text{min})$
• $u:\text{Uniform[0,1] random varible}$
• $\text{Beta}(x,y):\text{Beta function}$
• $\text{Mode formula valid when }\alpha >1,\text{ otherwise }\mathrm{Mode}(X)=\text{min}$

Spreadsheet Documents

• Phitter playground
• Download Excel Spreadsheet
• Excel file from GitHub repository
• Google spreadsheet document