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How many people need to be in a room for two to share a birthday? It’s less than you think. Here’s why

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Have you ever bumped into someone with the same birthday as you?

What about someone sharing a birthday in your workplace?

How common is a shared birthday, anyway?

Celebrate

The birthday problem, as it’s called by mathematicians, reveals problems with our understanding of number theory, probabilities and our assumptions of how the world works.

It comes back to how counter-intuitive maths is for a lot of people.

In the birthday problem, you are asked “What’s the minimum number of people in a room to get better than 50% chance of two people having the same birthday?”

A simple question with a puzzling answer.

To get a more intuitive understanding of this problem we’ve created an interactive simulation, below.

It arranges birthdays along a line, with January on the left and December on the right.

The intuitive answer is the wrong one

When the birthday problem is described to maths students for the first time, the majority of responses are that a group of 183 people is needed to have a better than even chance of two people having the same birthday.

The thinking here is: that 183 is half of 365 (the number of days in the year).

Students assume they only need to compare others against a single person – themselves, and then try to match their birthday with other people.

If you use this assumption, you need to find 183 people to have an even chance of finding a person matching with you.

However, when students understand that not every combination has to be with yourself – for example, person 2 and person 5 might be the right combination – it becomes clearer the number needed is lower than 183.

Combinations do not scale linearly

If you’ve been playing with the interactive above you may have come across the answer to the birthday problem: only about 23 people are needed for a greater than 50% chance of a shared birthday.

But how can this be if there are 15 times more days in the year?

We’ve created another interactive below to visualise how the connections between people in a room do not scale linearly as you add more people.

Play around with adding a node and see if you can guess how many connections should be added.

It should give you a better grasp of factorial growth through multiplication, which is the area of number theory that underpins the birthday problem.

Large numbers are hard to comprehend

The COVID-19 pandemic showed the world most of us have a limited understanding of exponential growth when presented with models of what could occur if the pandemic were left unchecked.

There are many great examples of the ill-understood power of exponential growth, but one I often use is asking this question: would you take $1 million on the first day of the month only, or one cent on the first day of the month, doubled each day until the end of the month (30 days)?

Nearly all people choose the $1 million lump sum.

However, if you choose the one-cent option, you end the month with approximately 10 times more money due to the effect of exponential growth.

In a similar tale, the supposed inventor of chess requested to sell their game to a king for some rice.

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Serendib News
Serendib News
Serendib News is a renowned multicultural web portal with a 17-year commitment to providing free, diverse, and multilingual print newspapers, featuring over 1000 published stories that cater to multicultural communities.

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