This is a great puzzle, and you get to learn a lot about probability along the way ... There are 30 people in a room ... what is the chance that any two of them celebrate their birthday on the same day? Assume 365 days in a year. Some people may think: "there are 30 people, and 365 days, so 30/365 sounds about right. But no! The probability is much higher. It is actually likely there are people who share a birthday in that room.
I will show you how to do it ... starting with a smaller example: Friends and Random Numbers
4 friends (Alex, Billy, Chris and Dusty) each choose a random number between 1 and 5. What is the chance that any of them chose the same number? We will add our friends one at a time ... First, what is the chance that Alex and Billy have the same number?Billy compares his number to Alex's number. There is a 1 in 5 chance of a match. As a tree diagram: Note: "Yes" and "No" together make 1 Now, let's include Chris ...But there are now two cases to consider (called "Conditional Probability"):
And we get this: For the top line (Alex and Billy did match) we already have a match (a chance of 1/5). But for the "Alex and Billy did not match" case there are 2 numbers that Chris could match with, so there is a 2/5 chance of Chris matching (against both Alex and Billy). And a 3/5 chance of not matching. And we can work out the combined chance by multiplying the chances it took to get there:
Following the "No, Yes" path ... there is a 4/5 chance of No, followed by a 2/5 chance of Yes: (4/5) × (2/5) = 8/25
Following the "No, No" path ... there is a 4/5 chance of No, followed by a 3/5 chance of No: (4/5) × (3/5) = 12/25 Also notice that adding all chances together is 1 (a good check that we haven't made a mistake): (5/25) + (8/25) + (12/25) = 25/25 = 1 Now what happens when we include Dusty?It is the same idea, just more of it: OK, that is all 4 friends, and the "Yes" chances together make 101/125: Answer: 101/125
But here is something interesting ... if we follow the "No" path we can skip all the other calculations and make our life easier: The chances of not matching are: (4/5) × (3/5) × (2/5) = 24/125 So the chances of matching are: 1 − (24/125) = 101/125 (And we didn't really need a tree diagram for that!) And that is a popular trick in probability: It is often easier to work out the "No" case
The "no match" case for:
So the chance of not matching is: (11/12) × (10/12) × (9/12) × (8/12) × (7/12) = 0.22... Flip that around and we get the chance of matching: 1 − 0.22... = 0.78... So, there is a 78% chance of any of them celebrating their Birthday in the same month And now we can try calculating the "Shared Birthday" question we started with:
It is just like the previous example! But bigger and more numbers: The chance of not matching: 364/365 × 363/365 × 362/365 × ... × 336/365 = 0.294... (I did that calculation in a spreadsheet, And the probability of matching is 1 − 0.294... : The probability of sharing a birthday = 1 − 0.294... = 0.706... Or a 70.6% chance, which is likely! So the probability for 30 people is about 70%. And the probability for 23 people is about 50%. And the probability for 57 people is 99% (almost certain!) SimulationWe can also simulate this using random numbers. Try it yourself here, use 30 and 365 and press Go. A thousand random trials will be run and the results given. You can also try the other examples from above, such as 4 and 5 to simulate "Friends and Random Numbers". For RealNext time you are in a room with a group of people why not find out if there are any shared birthdays? Footnote: In real life birthdays are not evenly spread out ... more babies are born in July, August, and September. Also Hospitals prefer to work on weekdays, not weekends, so there are more births early in the week. And then there are leap years. But you get the idea. Copyright © 2020 MathsIsFun.com |