Python Bernoulli Distribution in Statistics (original) (raw)

Last Updated : 31 Dec, 2019

scipy.stats.bernoulli() is a Bernoulli discrete random variable. It is inherited from the of generic methods as an instance of the rv_discrete class. It completes the methods with details specific for this particular distribution. Parameters :

x : quantilesloc : [optional]location parameter. Default = 0scale : [optional]scale parameter. Default = 1moments : [optional] composed of letters [‘mvsk’]; ‘m’ = mean, ‘v’ = variance, ‘s’ = Fisher’s skew and ‘k’ = Fisher’s kurtosis. (default = ‘mv’).Results : Bernoulli discrete random variable

Code #1 : Creating Bernoulli discrete random variable

Python3 1== `

importing library

from scipy.stats import bernoulli

numargs = bernoulli .numargs a, b = 0.2, 0.8 rv = bernoulli (a, b)

print ("RV : \n", rv)

`

Output :

RV : scipy.stats._distn_infrastructure.rv_frozen object at 0x0000016A4C0FC108

Code #2 : Bernoulli discrete variates and probability distribution

Python3 1== `

import numpy as np quantile = np.arange (0.01, 1, 0.1)

Random Variates

R = bernoulli .rvs(a, b, size = 10) print ("Random Variates : \n", R)

PDF

x = np.linspace(bernoulli.ppf(0.01, a, b), bernoulli.ppf(0.99, a, b), 10) R = bernoulli.ppf(x, 1, 3) print ("\nProbability Distribution : \n", R)

`

Output :

Random Variates : [0 0 0 0 0 0 0 0 0 1]

Probability Distribution : [ 4. 4. nan nan nan nan nan nan nan nan]

Code #3 : Graphical Representation.

Python3 1== `

import numpy as np import matplotlib.pyplot as plt

distribution = np.linspace(0, np.minimum(rv.dist.b, 2)) print("Distribution : \n", distribution)

plot = plt.plot(distribution, rv.ppf(distribution))

`

Output :

Distribution : [0. 0.02040816 0.04081633 0.06122449 0.08163265 0.10204082 0.12244898 0.14285714 0.16326531 0.18367347 0.20408163 0.2244898 0.24489796 0.26530612 0.28571429 0.30612245 0.32653061 0.34693878 0.36734694 0.3877551 0.40816327 0.42857143 0.44897959 0.46938776 0.48979592 0.51020408 0.53061224 0.55102041 0.57142857 0.59183673 0.6122449 0.63265306 0.65306122 0.67346939 0.69387755 0.71428571 0.73469388 0.75510204 0.7755102 0.79591837 0.81632653 0.83673469 0.85714286 0.87755102 0.89795918 0.91836735 0.93877551 0.95918367 0.97959184 1. ]

Code #4 : Varying Positional Arguments

Python3 1== `

import matplotlib.pyplot as plt import numpy as np

x = np.linspace(0, 5, 100)

Varying positional arguments

y1 = bernoulli.ppf(x, a, b) y2 = bernoulli.pmf(x, a, b) plt.plot(x, y1, "*", x, y2, "r--")

`

Output :