Poisson Approximation to the Binomial Distribution

Definition

If a random variable $X$ follows a binomial distribution with parameters $n$ and $p$ , written as

$X \sim \text{Bin}(n,p),$

then for large $n$ and small $p$ , with the product

$\lambda = np$

remaining moderate, the binomial distribution can be approximated by a Poisson distribution with mean $\lambda$ :

$X \approx \text{Poisson}(\lambda).$

Thus,

$P(X=k) \approx \frac{e^{-\lambda}\lambda^k}{k!}, \quad k=0,1,2,\dots$

This is called the Poisson approximation to the binomial distribution.

Main Content

1. First Concept: Binomial Distribution and Its Exact Probability

The binomial distribution models the number of successes in $n$ independent trials, where each trial has only two outcomes: success or failure.
Its exact probability mass function is

$P(X=k)=\binom{n}{k}p^k(1-p)^{n-k},$

where:

$n$ = number of trials
$p$ = probability of success in each trial
$k$ = number of successes

The binomial model is exact, but for very large $n$ , evaluating $\binom{n}{k}$ and the powers can be cumbersome.

Example:
If a factory produces thousands of items and the probability that an item is defective is very small, the number of defectives among many items follows a binomial distribution.

Why this matters:
The Poisson approximation begins with this binomial model and replaces it with a simpler model when conditions are suitable.

2. Second Concept: Conditions for Poisson Approximation

The approximation is valid when:
$n$ is large,
$p$ is small,
$np=\lambda$ is moderate (not too large).

This means the event of success is rare, but there are many opportunities for it to occur.

A common rule of thumb is that the Poisson approximation is reasonable when:

$n \ge 20$ and $p \le 0.05$ , or
$n$ is large enough that $np$ stays in a manageable range.

Interpretation:
When each individual trial has a very low probability of success, the total number of successes behaves like a count of rare events. The Poisson distribution is designed precisely for such counts.

Simple visual idea:

Trials: - - - - - - - - - - - - - - - -

Rare successes: - - S - - - - - S - - - - - -

Here, successes are sparse and scattered, which is the kind of pattern Poisson approximates well.

Example:
If the probability of a machine failure on a given day is 0.002 and you observe 1000 days, then $np = 1000 \times 0.002 = 2$ . Since the event is rare and the number of trials is large, Poisson approximation can be used.

3. Third Concept: Derivation of the Poisson Approximation

Starting from the binomial probability formula,

$P(X=k)=\binom{n}{k}p^k(1-p)^{n-k},$

we let

$p=\frac{\lambda}{n}.$

Then,

$P(X=k)=\binom{n}{k}\left(\frac{\lambda}{n}\right)^k\left(1-\frac{\lambda}{n}\right)^{n-k}.$

As $n$ becomes very large:

$\left(1-\frac{\lambda}{n}\right)^n \to e^{-\lambda}$
the combinatorial term behaves like $\frac{n^k}{k!}$ for fixed $k$

Combining these results gives:

$P(X=k)\approx \frac{e^{-\lambda}\lambda^k}{k!}.$

This is exactly the probability mass function of the Poisson distribution with mean $\lambda$ .

Meaning of the derivation:
The approximation works because many tiny probabilities across many trials accumulate into a distribution governed by the average rate $\lambda$ , not by the exact value of $n$ and $p$ separately.

Key insight:
The binomial distribution counts successes from repeated independent Bernoulli trials, while the Poisson distribution counts rare events over a fixed interval or number of opportunities.

Working / Process

1. Identify whether the binomial setting is appropriate

Check if the problem involves a fixed number of independent trials.
Confirm that each trial has two outcomes: success or failure.
Determine whether the success probability $p$ is small and $n$ is large.

2. Compute the Poisson parameter

Find $\lambda = np$ .
This value becomes the mean of the approximating Poisson distribution.
Use $\lambda$ in the Poisson formula instead of the full binomial expression.

3. Use the Poisson probability formula

For exactly $k$ successes,

$P(X=k) \approx \frac{e^{-\lambda}\lambda^k}{k!}.$

For probabilities like “at most 1” or “at least 2,” add the relevant Poisson terms.
Compare the result with the exact binomial probability if needed to judge accuracy.

Worked example:
Suppose $X \sim \text{Bin}(200, 0.01)$ . Find $P(X=3)$ .

Here, $n=200$ , $p=0.01$
$\lambda = np = 200 \times 0.01 = 2$
Approximate using Poisson:

$P(X=3)\approx \frac{e^{-2}2^3}{3!} = \frac{e^{-2}\cdot 8}{6} = \frac{4}{3}e^{-2} \approx 0.1804$

This is much easier than computing the exact binomial expression.

For cumulative probability:
If you need $P(X\le 1)$ ,

$P(X\le 1)\approx P(X=0)+P(X=1) = e^{-2}+\frac{2e^{-2}}{1!} = 3e^{-2} \approx 0.4060$

Advantages / Applications

Simplifies calculations

The Poisson formula is much easier to use than the binomial formula when $n$ is very large.
It avoids complicated binomial coefficients and large power computations.

Useful for rare events

It is ideal for modeling events with small success probabilities.
Common examples include defects, breakdowns, accidents, and misprints.

Widely used in real-life problems

Quality control: number of defective products in a large batch
Insurance: number of claims in a period
Telecommunications: number of calls arriving in a time interval
Biology/medicine: number of rare mutations or infections
Traffic/safety: number of accidents in a region or time period

Example applications:

If a newspaper has a very small chance of a printing error on each page and thousands of pages are printed, the number of errors can be approximated by Poisson.
If a website receives a huge number of visits and the chance of a server error on each request is tiny, the total errors may also be approximated this way.

Why it is important in practice:
The approximation allows analysts to make fast, reliable estimates without heavy computation, especially in large-scale systems.

Summary

The Poisson approximation is used when a binomial distribution has large $n$ and small $p$ .
It replaces $\text{Bin}(n,p)$ with $\text{Poisson}(\lambda)$ , where $\lambda = np$ .
It is especially effective for modeling rare events and simplifies probability calculations.

Important terms to remember:
Binomial distribution, Poisson distribution, rare events, approximation, probability mass function, $\lambda=np$ , large $n$ , small $p$