Beta Distribution

class BetaDistribution(amplitude: float = 1.0, alpha: float = 1.0, beta: float = 1.0, loc: float = 0.0, scale: float = 1.0, normalize: bool = False)

Bases: BaseDistribution

Class for Beta distribution.

Parameters:

• amplitude (float, optional) – The amplitude of the PDF. Defaults to 1.0. Ignored if normalize is True.

• alpha (float, optional) – The \(\alpha\) parameter. Defaults to 1.0.

• beta (float, optional) – The \(\beta\) parameter. Defaults to 1.0.

• loc (float, optional) – float, optional The location parameter, for shifting. Defaults to 0.0.

• scale (float, optional) – float, optional The scale parameter, for scaling. Defaults to 1.0.

• normalize (bool, optional) – bool, optional If True, the distribution is normalized so that the total area under the PDF equals 1. Defaults to False.

Raises:

• NegativeAmplitudeError – If the provided value of amplitude is negative.

• NegativeAlphaError – If the provided value of \(\alpha\) is negative.

• NegativeBetaError – If the provided value of \(\beta\) is negative.

Attributes:

mean

The mean of the distribution.

median

The median of the distribution.

mode

The mode of the distribution.

stddev

The standard deviation of the distribution.

variance

The variance of the distribution.

Methods

cdf(x)	Compute the cumulative density function (CDF) for the distribution.
logcdf(x)	Compute the log cumulative density function (logCDF) for the distribution.
logpdf(x)	Compute the log probability density function (logPDF) for the distribution.
pdf(x)	Compute the probability density function (PDF) for the distribution.
scipy_like(a, b[, loc, scale])	Instantiate BetaDistribution with scipy parameterization.
stats()	Computes and returns the statistical properties of the distribution, including,

Examples

Importing libraries

import matplotlib.pyplot as plt
import numpy as np
from scipy.stats import beta

from pymultifit.distributions import BetaDistribution

Generating a standard \(\text{Beta}(2, 30)\) distribution with pyMultiFit and scipy.

x_values = np.linspace(start=0, stop=1, num=500)

y_multifit = BetaDistribution(alpha=2, beta=30, normalize=True)
y_scipy = beta

Plotting PDF and CDF

f, ax = plt.subplots(1, 2, figsize=(12, 5))

ax[0].plot(x_values, y_scipy.pdf(x=x_values, a=2, b=30), label='Scipy Beta')
ax[0].plot(x_values, y_multifit.pdf(x_values), 'k:', label='pyMultiFit Beta')
ax[0].set_ylabel('f(x)')

ax[1].plot(x_values, y_scipy.cdf(x=x_values, a=2, b=30), label='Scipy Beta')
ax[1].plot(x_values, y_multifit.cdf(x_values), 'k:', label='pyMultiFit Beta')
ax[1].set_ylabel('F(x)')

f.suptitle('Beta(2, 30)')

for i in ax:
    i.set_xlabel('X')
    i.legend()
plt.tight_layout()

Generating a shifted and translated \(\text{Beta}(2, 30)\) distribution.

x_values = np.linspace(start=0, stop=10, num=500)

y_multifit = BetaDistribution(alpha=2, beta=30, loc=3, scale=5, normalize=True)
y_scipy = beta

Plotting PDF and CDF

f, ax = plt.subplots(1, 2, figsize=(12, 5))

ax[0].plot(x_values, y_scipy.pdf(x=x_values, a=2, b=30, loc=3, scale=5), label='Scipy Beta scaled')
ax[0].plot(x_values, y_multifit.pdf(x_values), 'k:', label='pyMultiFit Beta scaled')
ax[0].set_ylabel('f(x)')

ax[1].plot(x_values, y_scipy.cdf(x=x_values, a=2, b=30, loc=3, scale=5), label='Scipy Beta scaled')
ax[1].plot(x_values, y_multifit.cdf(x_values), 'k:', label='pyMultiFit Beta scaled')
ax[1].set_ylabel('F(x)')

f.suptitle('Beta(2, 30, 5, 3)')

for i in ax:
    i.set_xlabel('X')
    i.legend()
plt.tight_layout()

cdf(x)

Compute the cumulative density function (CDF) for the distribution.

Parameters:

x – Input array at which to evaluate the CDF.

logcdf(x)

Compute the log cumulative density function (logCDF) for the distribution.

Parameters:

x – Input array at which to evaluate the logCDF.

logpdf(x)

Compute the log probability density function (logPDF) for the distribution.

Parameters:

x – Input array at which to evaluate the logPDF.

pdf(x)

Compute the probability density function (PDF) for the distribution.

Parameters:

x – Input array at which to evaluate the PDF.

classmethod scipy_like(a: float, b: float, loc: float = 0.0, scale: float = 1.0)

Instantiate BetaDistribution with scipy parameterization.

Parameters:

a: float

The shape parameter, \(\alpha\).

b: float

The shape parameter, \(\beta\).

loc: float, optional

The location parameter. Defaults to 0.0.

scale: float, optional

The scale parameter,. Defaults to 1.0.

Returns:

BetaDistribution

An instance of normalized BetaDistribution.

stats()

Computes and returns the statistical properties of the distribution, including,

1. mean,

2. median,

3. variance, and

4. standard deviation.

Returns:

A dictionary containing statistical properties such as mean, variance, etc.

Return type:

Dict[str, float]

Notes

If any of the parameter is not computable for a distribution, this method returns None.

property mean

The mean of the distribution.

property median

The median of the distribution.

property mode

The mode of the distribution.

property stddev

The standard deviation of the distribution.

property variance

The variance of the distribution.

Note

The BetaDistribution encompasses the following specific cases:

1. ArcSineDistribution:

   • \(\alpha = \beta = 0.5\)

• UniformDistribution:

  • \(\alpha = \beta = 1\)

This class internally utilizes the following functions from utilities_d module:

• beta_pdf_()

• beta_cdf_()

Recommended Import

from pymultifit.distributions import BetaDistribution

Full Import

from pymultifit.distributions.beta_d import BetaDistribution