# Algorithm to generate Poisson and binomial random numbers?

i've been looking around, but i'm not sure how to do it.

A simple generator for random numbers taken from a Poisson distribution is obtained using this simple recipe: if x1, x2, ... is a sequence of random numbers with uniform distribution between zero and one, k is the first integer for which the product x1 · x2 · ... · xk+1 < e

i've found another page describing how to generate binomial numbers, but i think it is using an approximation of poisson generation, which doesn't help me.

For example, consider binomial random numbers. A binomial random number is the number of heads in N tosses of a coin with probability p of a heads on any single toss. If you generate N uniform random numbers on the interval (0,1) and count the number less than p, then the count is a binomial random number with parameters N and p.

i know there are libraries to do it, but i can't use them, only the standard uniform generators provided by the language (java, in this case).

• The book Numerical Recipes (3rd Edition) has a full explanation of generating Poisson and Binomial deviates Aug 6, 2009 at 21:39
• Some other available libraries are given here:
– user1707074
Sep 28, 2012 at 18:34

## Poisson distribution

``````init:
Let L ← e^(−λ), k ← 0 and p ← 1.
do:
k ← k + 1.
Generate uniform random number u in [0,1] and let p ← p × u.
while p > L.
return k − 1.
``````

In Java, that would be:

``````public static int getPoisson(double lambda) {
double L = Math.exp(-lambda);
double p = 1.0;
int k = 0;

do {
k++;
p *= Math.random();
} while (p > L);

return k - 1;
}
``````

## Binomial distribution

Going by chapter 10 of Non-Uniform Random Variate Generation (PDF) by Luc Devroye (which I found linked from the Wikipedia article) gives this:

``````public static int getBinomial(int n, double p) {
int x = 0;
for(int i = 0; i < n; i++) {
if(Math.random() < p)
x++;
}
return x;
}
``````

Neither of these algorithms is optimal. The first is O(λ), the second is O(n). Depending on how large these values typically are, and how frequently you need to call the generators, you might need a better algorithm. The paper I link to above has more complicated algorithms that run in constant time, but I'll leave those implementations as an exercise for the reader. :)

• @Kip In your first example, L stood for Lambda, what did P stand for? Jan 27, 2016 at 5:47
• @AkshatAgarwal Actually L stands for e^(−lambda). p is just a number between 0 and 1. Upon each iteration, it gets decreased by a random amount (when it is multiplied by a random number between 0 and 1) until you get to the point that p is less than L. The larger lambda is, the smaller (closer to 0) L will be, meaning the more iterations of the loop we will go through on average before p is less than L.
– Kip
Jan 28, 2016 at 16:17
• Is there a limit to `lambda`? When I pass 1000 or 2000 I get an average of 745 in the results. If I pass lower numbers the results seem correct. Nov 27, 2018 at 17:28

For this and other numerical problems the bible is the numerical recipes book.

There's a free version for C here: http://www.nrbook.com/a/bookcpdf.php (plugin required)

The C code should be very easy to transfer to Java.

This book is worth it's weight in gold for lots of numerical problems. On the above site you can also buy the latest version of the book.

• The Numerical Recipes book isn't free. You need to have a password to unlock the PDF files. Mar 11, 2010 at 16:10

Although the answer posted by Kip is perfectly valid for generating Poisson RVs with small rate of arrivals (lambda), the second algorithm posted in Wikipedia Generating Poisson Random variables is better for larger rate of arrivals due to numerical stability.

I faced problems during implementation of one of the projects requiring generation of Poisson RV with very high lambda due to this. So I suggest the other way.

There are several implementations from CERN in the following library (Java code):

http://acs.lbl.gov/~hoschek/colt/

Concerning binomial random numbers, it is based on the paper from 1988 "Binomial Random Variate Generation", that I recommend to you since they use an optimized algorithm.

Regards

``````implementation 'org.kie.modules:org-apache-commons-math:6.5.0.Final'