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### Course: Statistics and probability > Unit 9

Lesson 5: Binomial random variables- Binomial variables
- Recognizing binomial variables
- 10% Rule of assuming "independence" between trials
- Identifying binomial variables
- Binomial distribution
- Visualizing a binomial distribution
- Binomial probability example
- Generalizing k scores in n attempts
- Free throw binomial probability distribution
- Graphing basketball binomial distribution
- Binompdf and binomcdf functions
- Binomial probability (basic)
- Binomial probability formula
- Calculating binomial probability

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# Binomial probability (basic)

## Problem 1: Building intuition with free-throws

Steph makes $90\mathrm{\%}$ of the free-throws she attempts. She is going to shoot $3$ free-throws. Assume that the results of free-throws are independent from each other.

**She wants to find the probability that she makes exactly**$2$ of the $3$ free-throws.

To think about this problem, let's break it up into smaller parts.

## Generalizing from Problem 1: Building a formula for future use

We saw in Problem 1 that different orders of the same outcome each had the same probability.

We can build a formula for this type of problem, which is called a binomial setting. A binomial probability problem has these features:

- a set number of trials
$({n})$ - each trial can be classified as a "success" or "failure"
- the probability of success
is the same for each trial$({p})$ - results from each trial are independent from each other

Here's a summary of our general strategy for binomial probability:

Using the example from Problem 1:

free-throws$n=3$ - each free-throw is a "make" (success) or a "miss" (failure)
- probability she makes a free-throw is
${p}={0.90}$ - assume free-throws are independent

#### In general...

Try using these strategies to solve another problem.

## Problem 2

Steph's little brother Luke only has a $20\mathrm{\%}$ chance of making a free-throw. He is going to shoot $4$ free-throws.

## Challenge problem

Steph promises to buy Luke ice cream if he makes $3$ or more of his $4$ free-throws.

## Want to join the conversation?

- probability of each shot is given as .2. My doubt is if they are independent events, then in each shot probability of success or failure should be .5 ( as he is equally likely to fail or succeed). I am not clear on how .2 probability is arrived at?(1 vote)
- my friend, if I have understood you correctly, you are assuming that each shot has a FAIR chance of going in. That is, each shot you take has a 50% chance of going in. However, this is not the case for this given scenario. There exist a bias; the shooter has a 20% chance of making each shot. As for a 50% (or .5) chance scenario, a good example to consider is that of a fair coin. In this case, each coin flip has an equal opportunity to show heads or tails. Hence, there is no bias--the exact opposite scenario of that of the shooter in the above example.

Welp, hope that helps.(46 votes)

- How do you solve if you do not know the probability at all (i.e. 90% in first problem)? Or is there something I am not understanding about a question that asks probability of rolling a pair of dice x times and getting the sum of 10?

Example: Find the probability of throwing a sum of 10 at least 4 times in 9 throws.(4 votes)- Assuming that the dice is fair and six-sided, the probability is 1 in 6 to get a certain value.

For example: The probability of getting a 4 on a dice is 1/6.(5 votes)

- very helpful,thanks(5 votes)
- I seriously don't get the combination formula. All I did was multiply the probabilities, like 3(9/10*9/10*1/10), which works just as well, but I would like to understand the combination formula a bit better.(2 votes)
- In Combinations, we count all the unordered ways in which we can write a particular sequence. In permutations, we count all the ordered ways to write a particular sequence. Here we have to choose 2 places from 3 places where each chosen will corresponds to making a basket and each non-chosen place will correspond to missing a basket. e.g. From 123 position number we can choose 12, 13 or 23 position number where steph's can make a basket in 3 consecutive trials. The same can be chosen with the help of 3C2. Hope it helps. Thanks(5 votes)

- Hi, in Problem 2 I don't understand why there are more chances of scoring 3 or more free throwns out of 4, than scoring actually 3 out of 4. All in all I don't understand why it is ok to add the independent probabilites, getting an even better one. Thanks!!(3 votes)
- Hi, when scoring 3 or more free throws out of 4, the chances are: getting 3 out of 4; and getting 4 out of 4, however, when actually scoring exactly 3 out of the four there is only a chance of getting 3 out of 4 and so is less of a chance. I hope this helps answer your question.(1 vote)

- How would you put P(exactly 2 makes) in your calculator? I believe it's binomial pdf, but when I put it into my calculator I get a different answer. Thanks in advice for the assistance.(2 votes)
- I didn't realize the probability had changed between questions that was where I was going wrong. If you want to use your calculator, use Binomial PDF.(2 votes)

- For the challenge problem, instead of getting P(3 successes) + P(4 successes), I got the P(1 success) (0.410), added it to the P(2 successes) (0.154) which we already got in the previous question, then took it away from 1. But instead of the given answer, I got 0.436. Where did I go wrong?

If I get the probability of 1 success by adding the non-1 successes given in the explanations, I get P(2)=.154+P(3)=.026+P(4)=.002, giving a prob of 2 or more successes of 0.182, therefore a prob of 1 success of 1-0.182=0.818 This is very different from the prob of 1 successs I get from following the formula which gives .410 What is going on here?

In fact, I checked my answers in a spreadsheet and found the total probability doesn't add up to 1. How can this be?(2 votes)- I’m glad that you are in the habit of analyzing your answers, to check whether or not they make sense. What went wrong is that you did not include P(0 successes) in the list of probabilities that must add to 1.

Have a blessed, wonderful new year!(2 votes)

- For the "Steph promises to buy Luke ice cream if he makes 3 or more of his 4 free-throws" problem, the probability of 4 throws has, in the denominator, (4-4)! times 4!

Since 4-4=0, should the demoinator not be 0 as well (in the solution, the this does not happen. Instead it says 4! divided by 4! in the next step).(2 votes)- 0! is equal to 1 by definition i think(1 vote)

- OK I'm not getting this. In problem #1, why couldn't we use the basic probability formula: P(x)= number of possible ways X can occur/number of total possible outcomes = 3/8

i.e., there are 3 ways Steph can make 2 of 3 throws and there are 8 total possible outcomes (2x2x2)

?(1 vote)- The 8 possible sequences of makes and/or misses in 3 free throws are
**not**all equally likely, because the probability of making any given free throw (that is, 90%) is a percentage other than 50%. The basic probability formula you wrote in your question only applies for equally likely outcomes!

Have a blessed, wonderful day!(3 votes)

- The wording of the challenge problem is a bit ambiguous. I initially assumed 'he' refers to Steph rather than Luke.(2 votes)
- In the start, they refer Steph as a “she”.

Hope this helps!(1 vote)