# How to implement these 5 powerful probability distributions in Python

R is considered as the de facto programming language for statistical analysis right? But In this post, I will show you how to easily implement statistical concepts using Python.

I will implement discrete and continuous probability distributions using Python. I won’t get into the mathematical details of these distributions, but I will mention some of the best resources to learn the math concepts involved in these methods.

Before we jump into these probability distributions, I want to give a glimpse of what a random variable is. A random variable quantifies the outcomes of a number.

For example, a random variable for a coin flip can be represented as

X = { 1 heads

2 if tails}

A random variable is a variable that takes on a set of possible values (**discrete** or **continuous**) and is subject to *randomness*. Each possible value the random variable can take on is associated with a probability. The possible values the random variable can take on and the associated probabilities is known as probability distribution.

I encourage you to go through scipy.stats module.

There are two types of probability distributions, discrete and continuous probability distributions.

Discrete probability distributions are also called as probability mass functions. Some examples of discrete probability distributions are Bernoulli distribution, Binomial distribution, Poisson distribution and Geometric distribution.

Continuous probability distributions also known as probability density functions, they are functions that take on continuous values (e.g. values on the real line). Examples include the normal distribution, the exponential distribution and the beta distribution.

To understand more about discrete and continuous random variables, watch Khan academies probability distribution videos.

**Binomial Distribution**

A random variable X that has a binomial distribution represents the number of successes in a sequence of n independent yes/no trials, each of which yields success with probability p.

E(X) = np, Var(X) = np(1−p)

If you want to know how each function works, you can use *help file* command in your I python notebook. E(X) is the expected value or mean of the distribution.

Type *stats.binom?* to know about binom function.

*Example of binomial distribution: What is the probability of getting 2 heads out of 10 flips of a fair coin? *

In this experiment the probability of getting a head is 0.3, this means that on an average you can expect 3 coin flips to be heads. I define all the possible values the coin flip can take, k = np.arange(0,11), you can observe zero head, one head all the way upto ten heads. I am using *stats.binom.pmf* to calculate the probability mass function for each observation. It returns a list of 11 elements, these elements represent the probability associated with each observation.

You can simulate a binomial random variable using *.rvs*. The parameter size specifies how many simulations you want to do. I ask Python to return 10000 binomial random variables with parameters n and p. I am printing the mean and standard deviation of these 10000 random variables. Then I am going to plot the histogram of all the random variables that I simulated.

**Poisson Distribution**

A random variable X that has a Poisson distribution represents the number of events occurring in a fixed time interval with a rate parameters λ. λ tells you the rate at which the number of events occur. The average and variance is λ.

E(X) = λ, Var(X) = λ

You can notice that the number of accidents peaks around the mean. On an average you can expect lambda number of events. Try different values of lambda and n, then see how shape of the distribution changes.

Now I am going to simulate 1000 random variables from a Poisson distribution.

**Normal**** ****Distribution**

The normal distribution is a continuous distribution or a function that can take on values anywhere on the real line. The normal distribution is parameterized by two parameters: the mean of the distribution μ and the variance σ2.

Normal distribution can take values from minus infinity to plus infinity. You can notice that I am using *stats.norm.pdf * as normal distribution is a probability density function.

**Beta Distribution**

The beta distribution is a continuous distribution which can take values between 0 and 1. This distribution is parameterized by two shape parameters α and β.

The shape of beta distribution depends on the values of alpha and beta values. Beta distribution is predominantly used in Bayesian analysis.

**Exponential Distribution**

The exponential distribution represents a process in which events occur continuously and independently at a constant average rate.

I set the lambda parameter as 0.5 and x in the range of

Then I simulate 1000 random variables from an exponential distribution.* scale* is the inverse of lambda parameter. *ddof * in *np.std *is equal to dividing the standard deviation by n-1.

**Conclusion**

Distributions are like blue print for building a house, and random variable is summary of what happen in an experiment. I would recommend you to watch the lecture from harvard data science course, professor Joe Blitzstein gives a summary of everything you need to know about statistical models and distributions.

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