Unit 8 Probability And Sampling — Unit Plan

Title

Assessment

Lesson 1

Mystery Bags

Jada Draws Even

A large fish tank is filled with table tennis balls with numbers written on them. Jada chooses 10 table tennis balls from the tank and writes down their numbers.

A second tank is filled with golf balls with numbers written on them. Jada chooses 10 golf balls from the tank and writes down their numbers.

To win a prize, Jada must get a ball with an even number. Should she try to win the prize using the tank of table tennis balls or the tank of golf balls? Explain your reasoning.

Show Solution

Jada should use the tank of golf balls. Sample reasoning: From the tank of table tennis balls, Jada only gets 2 even numbers out of the 10 she chooses. From the tank of golf balls, she gets 7 even numbers out of the 10 she chooses. There seems to be a better chance of her getting even-numbered balls from the tank that has golf balls.

Lesson 2

Chance Experiments

According To

Here are some situations:

According to market research, a business has a 75% chance of making money in the first three years.
According to lab testing, $\frac{5}{6}$ of a certain kind of experimental light bulb will work after three years.
According to experts, the likelihood of a car needing major repairs in the first three years is 0.7.

Write these situations in order of likelihood from least to greatest after three years: The business makes money, the light bulb still works, and the car needs major repairs.
Select one of the situations. Write a chance experiment and event that has the same likelihood as the situation you selected.

Show Solution

The car needs major repairs, the business makes money, the light bulb still works.
Sample responses:
- flipping two coins and at least one not landing on heads
- rolling a standard number cube and it landing with any number other than 1 face up
- selecting a number greater than 3 when selecting a number between 1 and 10 randomly

Lesson 3

What Are Probabilities?

Letter of the Day

A mother decides to teach her son about a letter each day of the week. She will choose a letter from the name of the day. For example, on Saturday she might teach about the letter S or the letter U, but not the letter M.

What letters are possible to teach using this method? (There are 15.)
What are 4 letters that can't be taught using this method?
On TUESDAY, the mother writes the word on a piece of paper and cuts it up so that each letter is on a separate piece of paper. She mixes up the papers and picks one. What is the probability that she will choose the piece of paper with the letter Y? Explain your reasoning.

Show Solution

A, D, E, F, H, I, M, N, O, R, S, T, U, W, Y
Any 4 of B, C, G, J, K, L, P, Q, V, X, Z
$\frac{1}{7}$ . Sample reasoning: There are 7 outcomes in the sample space, all outcomes are equally likely, and there is only 1 outcome that corresponds to the letter Y.

Lesson 5

More Estimating Probabilities

The Probability of Spinning B

Jada, Diego, and Elena each use the same spinner that has four (not necessarily equal sized) sections marked A, B, C, and D.

Jada says, “The probability of spinning B is 0.3 because I spun 10 times, and it landed on B 3 times.”
Diego says, “The probability of spinning B is 20% because I spun 5 times, and it landed on B once.”
Elena says, “The probability of spinning B is $\frac{2}{7}$ because I spun 7 times, and it landed on B twice.”

Based on their methods, which probability estimate do you think is the most accurate? Explain your reasoning.
Andre measures the spinner and finds that the B section takes up $\frac{1}{4}$ of the circle. Explain why none of the methods match this probability exactly.

Show Solution

Sample response:

Jada's method is probably the most accurate since she had the most attempts.
Since Jada spun it 10 times, she could only get estimates in increments of 0.1. Since Diego spun it 5 times, he could only get estimates in increments of 20%. Since Elena spun it 7 times, she could only get estimates in increments of $\frac17$ . If they had spun the spinner more times, their results would probably get closer to $\frac14$ .

Lesson 6

Estimating Probabilities Using Simulation

Video Game Weather

In a video game, the chance of rain each day is always 30%. At the beginning of each day in the video game, the computer generates a random integer between 1 and 50. Explain how you could use this number to simulate the weather in the video game.

Show Solution

Sample response: If the number is between 1 and 15, the video game should create a rainy day. If the number is between 16 and 50, the video game should not create a rainy day.

Section A Check

Section A Checkpoint

Problem 1

A kindergarten teacher has a set of 20 cards to help students learn to count. Each card has a number of animals on it, from 1 to 20.

One child can count to 15 well, but has problems with 16 and after. When this child picks a card at random, what is the probability that it will be a number they have problems with?

Show Solution

\frac{5}{20}, \frac{1}{4}, 25\%

(or equivalent)

Problem 2

An environmental scientist can determine the health of a river based on whether a particular insect is present when they collect a sample of water. The scientist and students collect 25 samples from different parts of a river and notice that the insect is present in 12 of them.

The river is considered healthy if the probability of finding the insect in a sample is $\frac{1}{2}$ . Do you think this river could be considered healthy? Explain your reasoning.
What could the scientist do to better estimate the probability of finding the insect in a sample of river water?

Show Solution

Sample response:

I think it might be considered healthy. Sample reasoning: With a probability of $\frac{1}{2}$ , we might expect that 12.5 of the 25 samples have the insect. Because 12 samples had the insect, and that is pretty close to the expected 12.5, it might be close to a probability of $\frac{1}{2}$ .
The scientist could collect more samples.

Lesson 7

Simulating Multi-step Experiments

Battery Life

The probability of a certain brand of battery going dead within 15 hours is $\frac{1}{3}$ . Noah has a toy that requires 4 of these batteries. He wants to estimate the probability that at least one battery will die before 15 hours are up.

Noah will simulate the situation by putting marbles in a bag. Drawing one marble from the bag will represent the outcome of one of the batteries in the toy after 15 hours. Red marbles represent a battery that dies before 15 hours are up, and green marbles represent a battery that lasts longer.

How many marbles of each color should he put in the bag? Explain your reasoning.
After doing the simulation 5 times, Noah has these results. What should he use as an estimate of the probability that at least one battery will die within 15 hours?

trial result

1 GGRG

2 GRGR

3 GGGG

4 RGGG

5 GGGR

Show Solution

1 red marble and 2 green marbles (or some multiple of these). Sample reasoning: Based on the probability of each battery dying, $\frac{1}{3}$ of the marbles should be red.
$\frac{4}{5}$ or equivalent.

Lesson 9

Multi-step Experiments

A Number Cube and 10 Cards

Lin plays a game that involves a standard number cube and a deck of ten cards numbered 1 through 10. If both the cube and card have the same number, Lin gets another turn. Otherwise, play continues with the next player.

What is the probability that Lin gets another turn?

Show Solution

$\frac{6}{60}$ (or equivalent), since there are 6 outcomes for which the numbers match and 60 equally likely outcomes in the sample space ( $6 \boldcdot 10 = 60$ )

Section B Check

Section B Checkpoint

Problem 1

A cube is labeled so that when it is rolled, it shows only 1, 2, or 3 with equal chances of each one coming up. This cube is rolled, then 2 different coins are flipped.

How many outcomes are in the sample space? Explain your reasoning.
What is the probability that the cube shows 2, and the coins land showing the same face? Explain your reasoning.

Show Solution

12. Sample reasoning: The outcomes are 1HH, 1HT, 1TH, 1TT, 2HH, 2HT, 2TH, 2TT, 3HH, 3HT, 3TH, 3TT.
$\frac{2}{12}$ or equivalent. Sample reasoning: There are 2 outcomes that match the situation: 2HH and 2TT. There are 12 outcomes in the sample space, so the probability is $\frac{2}{12}$ .

Problem 2

A computer game shows that opening a prize box has a 25% chance that it contains your favorite character to play in the game.

How could you use coins to simulate opening 3 prize boxes to find the probability of getting your favorite character?

Show Solution

Sample response: Flip 2 coins three times to simulate opening 3 boxes. If both coins show heads any of the times, then it represents getting my favorite character. To find the probability, repeat this process many times and find the fraction of times this happens.

Lesson 11

Comparing Groups

Prices of Homes

Noah's parents are interested in moving to another part of town. They look up all the prices of the homes for sale and record them in thousands of dollars.

neighborhood 1 (mean: 75, MAD: 15)

120

neighborhood 2 (mean: 124, MAD: 15.6)

110

120

160

110

100

110

140

150

120

A dot plot, neighborhood 1, Home prices in Thousand Dollars, with the numbers 40 through 180, in intervals of 20, are indicated. — neighborhood 1

A dot plot, neighborhood 2, Home prices in Thousand Dollars, with the numbers 40 through 180, in intervals of 20, are indicated. — neighborhood 2

Decide whether the two groups are very different or not.

Show Solution

They are very different since the difference in means is 49, which is more than 3 times the larger MAD.

Lesson 12

Larger Populations

How Many Games?

Lin wants to know how many games middle school students in the United States have on their phones.

What is the population for Lin's question?
Explain why collecting data for this population would be difficult.
Give an example of a sample Lin could use to help answer her question.

Show Solution

All people who are in middle school in the United States who have a phone.
Sample response: There are too many people to collect data from everyone. It would take too much time, energy, and money to collect the data.
Sample response: 20 teens at Lin’s school.

Lesson 13

What Makes a Good Sample?

Reviews for School Lunches

Andre is designing a website that will display reviews of school lunches. Each item on the menu is rated from 0 to 5 stars. The main display can only show 6 reviews, so Andre needs to decide how to choose which reviews to show at the top.

This is a dot plot of all 40 reviews for the lasagna.

A dot plot for “number of stars.” The numbers 0 through 5 are indicated. The data are as follows: 0 stars, 10 dots. 1 star, 2 dots. 2 stars, 1 dot. 3 stars, 4 dots. 4 stars, 4 dots. 5 stars, 19 dots.

This is a dot plot of the stars shown on the first page of results.

A dot plot for “number of stars.” The numbers 0 through 5 are indicated. The data are as follows: 0 stars, 1 dot. 1 star, 1 dot. 2 stars, 1 dot. 3 stars, 1 dot. 4 stars, 1 dot. 5 stars, 1 dot.

If each rating also has a sentence or two explaining the rating, what are some good reasons to keep this sample displayed first? What are some good reasons to change the sample that is displayed first?
Is the sample representative of the population?

Show Solution

Sample response: It might be good to keep it so that students can see the wide range of reviews possible for the lasagna. It might be good to change it because there are a lot more 0 and 5 star ratings than ones in the middle, so maybe there should be more of those ratings shown.
It is not representative since the shape of the distributions are not similar.

Lesson 14

Sampling in a Fair Way

Sampling Spinach

A public health expert is worried that a recent outbreak of a disease may be related to a batch of spinach from a certain farm. She wants to test the plants at the farm, but it will ruin the crop if she tests all of them.

If the farm has 5,000 spinach plants, describe a method that would produce a random sample of 10 plants.
Why would a random sample be useful in this situation?

Show Solution

Sample responses:

She could number the plants from 1 to 5,000 and have a computer select 10 random numbers between 1 and 5,000, then test the plants that correspond to the numbers the computer generated.
Since it is not known where the disease may have originated, a random sample would hopefully produce a wide selection of plants that would be representative of the entire crop.

Section C Check

Section C Checkpoint

Problem 1

You want to know what percentage of schools in the United States have a math teacher as the football coach.

What is the population for this situation?
Why might it be important to use a sample for this situation?
What is a possible sample you could use for this situation?

Show Solution

All of the schools in the United States
Sample response: It would be difficult to get data from every school in the United States, so we could use a sample to estimate the percentage.
Sample response: We could pick a few schools from each state.

Problem 2

Kiran wants to know what students at his school think about the theme for the homecoming dance. He is sitting with a group of friends at lunch, so he decides to ask them and use their responses as a sample.

Why might this method for getting a sample not reflect the data for the population?
Why might using more randomness in selecting people for the sample be better?

Show Solution

Sample response:

Because all of the people in the sample are friends, they might have similar interests and be biased one way or another and not match what the people in the school think.
It will help avoid bias and be more likely to collect information from a group more representative of the population.

Lesson 15

Estimating Population Measures of Center

More Accurate Estimate

Here are dot plots that represent samples from two different populations.

Sample 1:

Sample 2:

Estimate the mean of each population using these samples.
Based on the dot plots, which estimate is more likely to be accurate? Explain your reasoning.

Show Solution

Correct responses should be close to 25 and 50 respectively.
The estimate for Sample 1 is probably more accurate since there is much less variability in the data.

Lesson 17

More about Sampling Variability

How Much Mail?

Jada collects data about the number of letters people get in the mail each week. The population distribution is shown in the dot plot.

A dot plot with the numbers 14 through 36, in increments of 2, indicated.

Which of these dot plots are likely to represent the means from samples of size 10 from this population? Explain your reasoning.

Dot Plot 1

Dot Plot 2

Show Solution

Dot Plot 2. Sample reasoning: It has the same center, but less variability than the population data. Dot Plot 1 also has less variability, but has a different center than the population data, so it is probably not generated by sample means from the original population.

Lesson 18

Comparing Populations Using Samples

Teachers Watching Movies

Noah is interested in comparing the number of movies watched by students and teachers over the winter break. He takes a random sample of 10 students and 10 teachers and makes a dot plot of their responses.

A dot plot for “movies watched over break” titled "Students." The numbers 0 through 8 are indicated. The data are as follows: 4 movies, 1 dot. 5 movies, 3 dots. 6 movies, 4 dots. 7 movies, 2 dots. — students

<p>dot plot for “movies watched over break” titled "Teachers.” 0 to 8, by 1’s.</p><br> — teachers

Noah then computes the measures of center and variability for each group:

Students: mean: 5.7 movies, MAD: 0.76 movies
Teachers: mean: 2.7 movies, MAD: 0.9 movies

Should Noah conclude that there is a meaningful difference in the mean number of movies watched over winter break between the two groups? Explain your reasoning.

Show Solution

Yes. Sample reasoning: Because the difference in the means is greater than 2 MADs, there is a meaningful difference in the mean number of movies watched. $(5.7 - 2.7) \div 0.9 \approx 3.33$

Lesson 19

Comparing Populations with Friends

A Different Box Plot

Use the box plot to answer the questions.

<p>Box plot from 40 to 78 by 2’s. Whisker from 42 to 46. Box from 46 to 52 with vertical line at 48. Whisker from 52 to 55.</p><br>

What measure of center is shown in the box plot? What measure of variability? What are the values for each of these characteristics?
Draw another box plot with the same measure of variability that is meaningfully different from the one shown.

Show Solution

Median: 48, IQR: 6
Correct responses show a box plot with an IQR of 6 and median greater than or equal to 60 (or less than or equal to 36).

Section D Check

Section D Checkpoint

Problem 1

A company selects 20 people at random to say whether they use social media to get news. The people can select from the following options: never, rarely, sometimes, or often. Here are the results.

often
sometimes
never
sometimes
never
rarely
sometimes
never
sometimes
never
never
never
never
rarely
rarely
never
sometimes
sometimes
often
often

Based on this sample, what proportion of the population gets their news from social media sometimes or often?
A headline for a newspaper uses this study to say, “Half of Americans Get Their News from Social Media.” Is the headline misleading or does it fit with what the sample shows? Explain your reasoning.

Show Solution

$\frac{9}{20}$
Sample response: I think it fits with what the sample shows. $\frac{9}{20}$ is very close to $\frac{1}{2}$ , and it is reasonable to use that benchmark fraction for this case.

Problem 2

A traveler is visiting Buffalo, New York, and wants to check the difference in price between getting a hotel room and renting a house for a short-term stay. The mean price of each option for one night is listed.

hotel: $144
house: $212

What is a value for the MAD that would indicate that there is a meaningful difference between the price of the two options? Explain your reasoning.

Show Solution

Sample response: Any value less than $34. Sample reasoning:

(212 - 144) \div 2 = 34

, so the difference of the means would be greater than twice the MAD.

Lesson 20

Memory Test

No cool-down

Unit 8 Assessment

End-of-Unit Assessment

Problem 1

Elena would like to know the average height of seventh graders in her school district. She measures the heights of everyone in a random sample of 20 students. The mean height of Elena’s sample is 61 inches, and the MAD (mean absolute deviation) is 2 inches.

Select all the true statements.

The median height of the sample must be between 59 and 63 inches.

Another random sample of 20 students is likely to have a mean between 57 and 65 inches.

The mean height of these 20 students is likely to be exactly the same as the mean height of all students in the district.

The mean height of these 20 students is likely to be exactly the same as the mean height of a second random sample of 20 students.

Elena would be more likely to get an accurate estimate of the mean height of the population by sampling 40 people instead of sampling 20 people.

Show Solution

B, E

Problem 2

Here is a dot plot showing how much time customers spent in a store, rounded to the nearest five minutes.

Dot plot from 0 to 50. Time in store in minutes. Beginning at 0, number of dots above each increment is 0, 17, 4, 3, 4, 8, 9, 6, 2, 0, 0.

Which of the following is a representative sample of this population?

A dot plot, A, from 0 to 50. Time in store in minutes. — A

<p>A dot plot, B, from 0 to 50. Time in store in minutes.</p> — B

A dot plot, C, from 0 to 50. Time in store in minutes. — C

A dot plot, D, from 0 to 50. Time in store in minutes. — D

Show Solution

Problem 3

The heights for a random sample of 50 volleyball players across the United States are summarized in this histogram.

<p>Histogram from 66 to 80 by 2’s. Height in inches. Beginning at 66 up to but not including 68, height of bar at each interval is 2,3,13,17,7,5,1.</p><br>

Select all of the information that would be reasonable to estimate from this sample.

A.The median height for volleyball players on a single team is about 73 inches.

B.The median height for volleyball players in the United States is about 73 inches.

C.There are no volleyball players in the United States taller than 80 inches.

D.The mean height for volleyball players in the United States is about 73 inches.

E.The mean height for basketball players in the United States is about 73 inches.

Show Solution

B, D

Problem 4

An administrator of a large middle school is installing some vending machines in the cafeteria and teacher’s lounge. She wants to know what type of machine would be most popular.

What is the population for the administrator’s question?
Give an example of a sample the administrator could use to help answer her question that is likely to be representative.

Show Solution

Sample response:

The population is current students, teachers, and staff of the school.
Use a list of students, teachers, and staff, and select 30 of them at random.

Problem 5

All the students at 2 different schools take the same assessment. The principal at each school uses the scores from one class at their school to prepare information to share. Here is what they brought.

School A:

Mean: 68.8
Median: 72
MAD: 8.02
IQR: 20

School B:

Box plot from 55 to 100 by 5’s. Whisker from 60 to 70. Box from 70 to 80 with vertical line at 75. Whisker from 80 to 90.

Which school has better typical results on the exam?
Which school has greater variability in the results?

Show Solution

School B
School A

Problem 6

A box by the exit of a store has a sign asking, “Were you happy with your experience today?” Customers may write yes or no on a slip of paper and leave it in the box. The store owner stops 12 people on their way out and asks them the same question. These are the results:

yes, yes, yes, no, yes, no, yes, yes, no, yes, no, yes

Based on these 12 responses, estimate the proportion of all shoppers who are happy with their experience that day.
After collecting the papers from the box, it shows that only 25% of the slips are marked yes. What might explain the difference between the actual results and the owner’s survey? How could the owner have done the survey better?

Show Solution

Sample response:

$\frac{8}{12}$ or $\frac{2}{3}$ . (Any answer between 0.6 and 0.75 is reasonable.)
The sample was not selected using a random process. The owner should have tried to select people for the survey using more randomness to reduce bias.

Minimal Tier 1 response:

Work is complete and correct.
Sample:

$\frac{8}{12}$
The survey wasn’t random. Use more randomness to get the sample.

Tier 2 response:

Work shows general conceptual understanding and mastery, with some errors.
Sample errors: Proportion is close to but not in correct range; the selection of the sample is given as a reason for the difference, but randomness is not mentioned exactly.

Tier 3 response:

Significant errors in work demonstrate lack of conceptual understanding or mastery.
Sample errors: Proportion wildly out of range, including greater than 1 or less than 0; another reasoning for the different results is given that does not account for a random process.

Problem 7

A scientist wants to know if there is a meaningful difference between two groups of gels that grow bacteria. He randomly selects six gels from each group, and counts the number of bacteria spots on each gel:

Group A: 9, 12, 13, 13, 14, 17

Group B: 8, 6, 5, 8, 13, 8

Is there a meaningful difference between the two groups? Show all calculations that lead to your answer.

Show Solution

Yes, there is a significant difference. Use either mean and MAD (mean absolute deviation) or median and IQR (interquartile range) to decide. Using the means, the mean of Group A is 13, and the MAD is 1.67. The mean of Group B is 8, and the MAD is 1.67. The difference in means is 3 MADs, so it is a meaningful difference. Using the medians, the median of Group A is 13, and the IQR is 2. The median of Group B is 8, and the IQR is 2. The difference in medians is 2.5 IQRs, so it is a meaningful difference.

Minimal Tier 1 response:

Work is complete and correct, with complete explanation or justification.
Sample: Yes, there is a meaningful difference. The median of Group A is 13. The median of Group B is 8. The IQR of each group is 2. The difference in medians is more than 2 IQRs.

Tier 2 response:

Work shows good conceptual understanding and mastery, with either minor errors or correct work with insufficient explanation or justification.
Sample errors: Minor visible calculation errors cause one or two means, medians, MADs or IQRs to be incorrect. Acceptable errors: An error in calculating causes an incorrect conclusion about whether there is a meaningful difference between the two groups; an error in calculating mean or median leads to a corresponding error in calculating MAD or IQR.

Tier 3 response:

Work shows a developing but incomplete conceptual understanding, with significant errors.
Sample errors: Response using median and IQR does not sort Group B’s data, but otherwise correctly works through the problem; conclusion about significant differences between the groups is driven only by means or medians and not MAD or IQR; incorrect conclusion about significant differences based on correct work; mixing center and spread measures, such as using mean and IQR; incorrect calculations with no work shown but a correct conclusion based on the results.

Tier 4 response:

Work includes major errors or omissions that demonstrate a lack of conceptual understanding and mastery.
Sample errors: Incorrect algorithm for calculating mean, median, MAD, or IQR; no use of these measures in problem work.