Solution Manual for Introductory Statistics: Exploring the World Through Data, 3rd Edition

INSTRUCTOR’S SOLUTIONS MANUAL I NTRODUCTORY S TATISTICS : E XPLORING THE W ORD T HROUGH D ATA THIRD EDITION Robert Gould University of California, Los Angeles Rebecca Wong West Valley College Colleen Ryan Moorpark Community College The author and publisher of this book have used their best efforts in preparing this book. These efforts include the development, research, and testing of the theories and programs to determine their effectiveness. The author and publisher make no warranty of any kind, expressed or implied, with regard to these programs or the documentation contained in this book. The author and publisher shall not be liable in any event for incidental or consequential damages in connection with, or arising out of, the furnishing, performance, or use of these programs. Reproduced by Pearson from electronic files supplied by the author. Copyright © 2020 by Pearson Education, Inc. 221 River Street, Hoboken, NJ 07030. All rights reserved. All rights reserved. No part of this publication may be reproduced, stored in a retrieval system, or transmitted, in any form or by any means, electronic, mechanical, photocopying, recording, or otherwise, without the prior written permission of the publisher. Printed in the United States of America. ISBN-13: 978-0-13-519061-6 ISBN-10: 0-13-519061-4 CONTENTS Chapter 1: Introduction to Data Section 1.2: Classifying and Storing Data ……………………………………………………………1 Section 1.3: Investigating Data …………………………………………………………………………..3 Section 1.4: Organizing Categorical Data ……………………………………………………………3 Section 1.5: Collecting Data to Understand Causality……………………………………………6 Chapter Review Exercises …………………………………………………………………………………7 Chapter 2: Picturing Variation with Graphs Section 2.1: Visualizing Variation in Numerical Data and Section 2.2: Summarizing Important Features of a Numerical Distribution ….9 Section 2.3: Visualizing Variation in Categorical Variables and Section 2.4: Summarizing Categorical Distributions ………………………………..14 Section 2.5: Interpreting Graphs ……………………………………………………………………….15 Chapter Review Exercises ……………………………………………………………………………….16 Chapter 3: Numerical Summaries of Center and Variation Section 3.1: Summaries for Symmetric Distributions ………………………………………….19 Section 3.2: What’s Unusual? The Empirical Rule and z-Scores …………………………..22 Section 3.3: Summaries for Skewed Distributions ………………………………………………23 Section 3.4: Comparing Measures of Center ………………………………………………………24 Section 3.5: Using Boxplots for Displaying Summaries ………………………………………27 Chapter Review Exercises ……………………………………………………………………………….28 Chapter 4: Regression Analysis: Exploring Associations between Variables Section 4.1: Visualizing Variability with a Scatterplot ………………………………………..31 Section 4.2: Measuring Strength of Association with Correlation …………………………31 Section 4.3: Modeling Linear Trends ………………………………………………………………..32 Section 4.4: Evaluating the Linear Model ………………………………………………………….37 Chapter Review Exercises ……………………………………………………………………………….40 Chapter 5: Modeling Variation with Probability Section 5.1: What Is Randomness? ……………………………………………………………………49 Section 5.2: Finding Theoretical Probabilities…………………………………………………….49 Section 5.3: Associations in Categorical Variables ……………………………………………..54 Section 5.4: Finding Empirical and Simulated Probabilities …………………………………56 Chapter Review Exercises ……………………………………………………………………………….58 Copyright © 2020 Pearson Education, Inc. iii Chapter 6: Modeling Random Events: The Normal and Binomial Models Section 6.1: Probability Distributions Are Models of Random Experiments …………..65 Section 6.2: The Normal Model………………………………………………………………………..67 Section 6.3: The Binomial Model (Optional) ……………………………………………………..79 Chapter Review Exercises ……………………………………………………………………………….81 Chapter 7: Survey Sampling and Inference Section 7.1: Learning about the World through Surveys ………………………………………85 Section 7.2: Measuring the Quality of a Survey ………………………………………………….86 Section 7.3: The Central Limit Theorem for Sample Proportions ………………………….88 Section 7.4: Estimating the Population Proportion with Confidence Intervals ………..90 Section 7.5: Comparing Two Population Proportions with Confidence………………….94 Chapter Review Exercises ……………………………………………………………………………….97 Chapter 8: Hypothesis Testing for Population Proportions Section 8.1: The Essential Ingredients of Hypothesis Testing …………………………….101 Section 8.2: Hypothesis Testing in Four Steps ………………………………………………….102 Section 8.3: Hypothesis Tests in Detail ……………………………………………………………107 Section 8.4: Comparing Proportions from Two Populations ……………………………….108 Chapter Review Exercises ……………………………………………………………………………..112 Chapter 9: Inferring Population Means Section 9.1: Sample Means of Random Samples ………………………………………………121 Section 9.2: The Central Limit Theorem for Sample Means ……………………………….122 Section 9.3: Answering Questions about the Mean of a Population……………………..123 Section 9.4: Hypothesis Testing for Means ………………………………………………………125 Section 9.5: Comparing Two Population Means ……………………………………………….131 Chapter Review Exercises ……………………………………………………………………………..138 Chapter 10: Associations between Categorical Variables Section 10.1: The Basic Ingredients for Testing with Categorical Variables …………147 Section 10.2: The Chi-Square Test for Goodness of Fit ……………………………………..149 Section 10.3: Chi-Square Tests for Associations between Categorical Variables ……………………………………………………………………………….153 Section 10.4: Hypothesis Tests When Sample Sizes Are Small…………………………..160 Chapter Review Exercises ……………………………………………………………………………..165 Chapter 11: Multiple Comparisons and Analysis of Variance Section 11.1: Multiple Comparisons………………………………………………………………..173 Section 11.2: The Analysis of Variance …………………………………………………………..175 Section 11.3: The ANOVA Test ……………………………………………………………………..176 Section 11.4: Post-Hoc Procedures ………………………………………………………………….180 Chapter Review Exercises ……………………………………………………………………………..184 Copyright © 2020 Pearson Education, Inc. iv Chapter 12: Experimental Design: Controlling Variation Section 12.1: Variation Out of Control …………………………………………………………….187 Section 12.2: Controlling Variation in Surveys …………………………………………………192 Section 12.3: Reading Research Papers ……………………………………………………………192 Chapter 13: Inference without Normality Section 13.1: Transforming Data …………………………………………………………………….197 Section 13.2: The Sign Test for Paired Data……………………………………………………..199 Section 13.3: Mann-Whitney Test for Two Independent Groups…………………………201 Section 13.4: Randomization Tests………………………………………………………………….203 Chapter Review Exercises ……………………………………………………………………………..204 Chapter 14: Inference for Regression Section 14.1: The Linear Regression Model……………………………………………………..209 Section 14.2: Using the Linear Model ……………………………………………………………..210 Section 14.3: Predicting Values and Estimating Means ……………………………………..212 Chapter Review Exercises ……………………………………………………………………………..213 Copyright © 2020 Pearson Education, Inc. v Chapter 1: Introduction to Data Section 1.2: Classifying and Storing Data 1.1 There are eight variables: “Female”, “Commute Distance”, “Hair Color”, “Ring Size”, “Height”, “Number of Aunts”, “College Units Acquired”, and “Living Situation”. 1.2 There are eleven observations. 1.3 a. Living situation is categorical. b. Commute distance is numerical. c. Number of aunts is numerical. a. Ring size is numerical. b. Hair color is categorical. c. Height is numerical. 1.4 1.5 Answers will vary but could include such things as number of friends on Facebook or foot length. Don’t copy these answers. 1.6 Answers will vary but could include such things as class standing (“Freshman”, “Sophomore”, “Junior”, or “Senior”) or favorite color. Don’t copy these answers. 1.7 0 = male, 1 = female. The sum represents the total number females in the data set. 1.8 There would be seven 1’s and four 0’s. 1.9 Female is categorical with two categories. The 1’s represent females, and the 0’s represent males. If you added the numbers, you would get the number of females, so it makes sense here. 1.10 a. Freshman 0 1 1 0 1 1 0 1 1 0 0 b. numerical c. categorical 1.11 a. The data is stacked. b. 1 = male, 0 = female. c. Male 1916 183 836 95 512 Female 9802 153 1221 Copyright © 2020 Pearson Education, Inc. 1 2 Introductory Statistics: Exploring the World Through Data, 3rd edition 1.12 a. The data is unstacked. b. Labels for columns will vary. Gender Age 1 29 1 23 1 30 1 32 1 25 0 24 0 24 0 32 0 35 0 23 c. Gender is categorical; Age is numerical 1.13 a. Stacked and coded: Calories 90 310 500 500 600 90 150 600 500 550 Sweet 1 1 1 1 1 1 0 0 0 0 The second column could be labeled “Salty” with the 1’s being 0’s and the 0’s being 1’s. b. Unstacked: Sweet 90 310 500 500 600 90 1.14 a. Salty 150 600 500 550 Stacked and coded: Cost Male 10 1 15 1 15 1 25 1 12 1 8 0 30 0 15 0 15 0 The second column could be labeled “Female” with the 1’s being 0’s and the 0’s being 1’s. Copyright © 2020 Pearson Education, Inc. Chapter 1: Introduction to Data b. Unstacked: Male Female 10 15 15 25 12 8 30 15 15 Section 1.3: Investigating Data 1.15 Yes. Use College Units Acquired and Living Situation. 1.16 Yes. Use Female and Height. 1.17 No. Data on number of hours of study per week are not included in the table. 1.18 Yes. Use Ring Size and Height. 1.19 a. Yes. Use Date. b. No. data on temperature are not included in the table. c. Yes. Use Fatal and Species of Shark. d. Yes. Use Location. 1.20 Use Time and Activity. Section 1.4: Organizing Categorical Data 1.21 a. 33/40 = 82.5% b. 32/45 = 71.1% c. 33/65 = 50.8% d. 82.5% of 250 = 206 1.22 a. 4/27 = 14.8% b. 14/27 = 51.9% c. 4/18 = 22.2% d. 14.8% of 600 = 89 men 1.23 a. 15/38 = 39.5% of the class were male. b. 0.64(234) = 149.994, so 150 men are in the class. c. 0.40(x) = 20, so 20/0.40 = 50 total students in the class. 1.24 a. 0.35(346) = 121 male nurses. b. 66/178 = 37.1% female engineers. c. 0.65(x) = 169 so 169/0.65 = 260 lawyers in the firm. 1.25 The frequency of women 6, the proportion is 6/11, and the percentage is 54.5%. 1.26 The frequency is 8, the proportion is 8/11, and the percentage is 72.7%. Copyright © 2020 Pearson Education, Inc. 3 4 Introductory Statistics: Exploring the World Through Data, 3rd edition 1.27 a. and b. Dorm Commuter Total c. 4/6 = 66.7% d. 4/7 = 57.1% e. 7/11 = 63.6% f. 66.7% of 70 = 47 Men Women 3 2 5 4 2 6 Total 7 4 11 Men 3 2 0 5 Women 5 0 1 6 Total 8 2 1 11 1.28 a. and b. Brown Black Blonde Total c. 5/6 = 83.3% d. 5/8 = 62.5% e. 8/11 = 72.7% f. 83.3% of 60 = 50 1.29 1.26(x) = 160328 so 160328/1.26 = 127,244 personal care aids in 2014 1.30 .1295(x) = 3480000 so 3480000/.1295 = $26,872,587.87 total candy sales 1.31 State California New York Illinois Louisiana Mississippi Prison 136,088 52518 48278 30030 18793 Rank Prison 1 2 3 4 5 Population 39,144,818 19,795,791 12,859,995 4,670,724 2,992,333 Population (thousands) 39145 19796 12860 4671 29922 Prison per 1000 3.48 2.65 3.75 6.43 6.28 California has the highest prison population. Louisiana has the highest rate of imprisonment. The two answers are different because the state populations are different. 1.32 a. Miami: 4,919,000/2891 = 1701 Detroit: 3,903,000/3267 = 1195 Atlanta: 3,500,000/5083 = 689 Seattle: 2,712,000/1768 = 1534 Baltimore: 2,076,000/1768 = 1174 Ranks: 1- Miami, 2- Seattle, 3- Detroit, 4- Baltimore, 5- Atlanta b. Atlanta c. Miami Copyright © 2020 Pearson Education, Inc. Rank Rate 4 5 3 1 2 Chapter 1: Introduction to Data 5 1.33 Year 1990 2000 %Uncovered 34, 719  13.9% 249, 778 36,586  13.1% 279, 282 29758  9.4% 316574 The percentage of uninsured people have been declining. 2015 1.34 Year % Subscribers 103.6  90.3% 2012 114.7 103.3  90.5% 2013 114.1 103.7  89.6% 2014 115.7 100.2  86.0% 2015 116.5 97.8  84.0% 2016 116.4 The percentage of cable subscribers rose slightly between 2012 and 2013 but has declined each year since then. 1.35 %Older Population 54.8  16.4% 2020 334 70.0  19.6% 2030 358 81.2  21.4% 2040 380 88.5  22.1% 2050 400 The percentage of older population is projected to increase. Year 1.36 %Older Population 4.0  48.8% 2000 8.2 3.6  47.4% 2005 7.6 3.6  52.9% 2010 6.8 3.2  46.4% 2014 6.9 The rate has fluctuating over this period, decreasing, then increasing, and then decreasing again. Year Copyright © 2020 Pearson Education, Inc. 6 Introductory Statistics: Exploring the World Through Data, 3rd edition 1.37 We don’t know the percentage of female students in the two classes. The larger number of women at 8a.m. may just result from a larger number of students at 8 a.m., which may be because the class can accommodate more students because perhaps it is in a large lecture hall. 1.38 No, we need to know the population of each city so we can compare the rates. Section 1.5 Collecting Data to Understand Causality 1.39 Observational study. 1.40 Controlled experiment. 1.41 Controlled experiment. 1.42 Controlled experiment. 1.43 Controlled experiment. 1.44 Observational study. 1.45 Anecdotal evidence are stories about individual cases. No cause-and effect conclusions can be drawn from anecdotal evidence. 1.46 These testimonials are anecdotal evidence. There is no control group and no comparison. No cause-and-effect conclusions can be drawn from anecdotal evidence. 1.47 This was an observational study, and from it you cannot conclude that the tutoring raises the grades. Possible confounders (answers may vary): 1. It may be the more highly motivated who attend the tutoring, and this motivation is what causes the grades to go up. 2. It could be that those with more time attend the tutoring, and it is the increased time studying that causes the grades to go up. 1.48 a. If the doctor decides on the treatment, you could have bias. b. To remove this bias, randomly assign the patients to the different treatments. c. If the doctor knows which treatment a patient had, that might influence his opinion about the effectiveness of the treatment. d. To remove that bias, make the experiment double-blind. The talk-therapy-only patients should get a placebo, and no patients should know whether they have a placebo or antidepressant. In addition, the doctor should not know who took the antidepressants and who did not. 1.49 a. The sample size of this study is not large (40). The study was a controlled experiment and used random assignment. It was not double-blind since researchers new what group each participant was in. b. The sample size of the study was small, so we should not conclude that physical activity while learning caused higher performance. 1.50 This is an observational study because researchers did not determine who received PCV7 and who did not. You cannot conclude causation from an observational study. We must assume that it is possible that there were confounding factors (such as other advances in medicine) that had a good effect on the rate of pneumonia. 1.51 a. Controlled experiment. Researchers used random assignment of subjects to treatment or control groups. b. Yes. The experiment had a large sample size, was controlled, randomized, and double-blind; and used a placebo. 1.52 a. Observational study. There was no random assignment to treatment/control groups. The subjects kept a food diary and had their blood drawn. b. We cannot make a cause-and-effect conclusion since this was an observational study. 1.53 No, this was not a controlled experiment. There was no random assignment to treatment/control groups and no use of a placebo. Copyright © 2020 Pearson Education, Inc. Chapter 1: Introduction to Data 7 1.54 No. There was no control group and no comparison. From observation of 12 children it is not possible to come to a conclusion that the vaccine causes autism. It may simply be that autism is usually noticed at the same age the vaccine is given. 1.55 a. Intervention remission: 11/33 = 33.3%; Control remission: 3 /34 = 8.8% b. Controlled experiment. There was random assignment to treatment/control groups. c. While this study did use random assignment to treatment/control groups, the sample size was fairly small (67 total) and there was no blinding in the experimental design. The difference in remission may indicate that the diet approach is promising and further research in this area is needed. 1.56 Ask whether there was random assignment to groups. Without random assignment there could be bias, and we cannot infer causation. 1.57 No. This is an observational study. 1.58 This is likely a conclusion from observational studies since it would not be ethical to randomly assign a subject to a group that drank large quantities of sugary drinks. Since this was likely based on observational studies, we cannot conclude drinking sugary beverages causes lower brain volume. Chapter Review Exercises 1.59 a. 61/98 = 62.2% b. 37/82 = 45.1% c. Yes, this was a controlled experiment with random assignment. The difference in percentage of homes adopting smoking restrictions indicates the intervention may have been effective. 1.60 No. Cause-and-effect conclusions cannot be drawn from observational studies. 1.61 a. Gender (categorical) and whether students had received a speeding ticket (categorical) b. c. 1.62 a. Male Female Yes 6 5 No 4 10 Men: 6/10=60%; Women: 5/15 = 33.3%; a greater percentage of men reported receiving a speeding ticket. Gender (categorical) and whether students had driven over 100 mph (categorical). b. c. Male Female Yes 6 5 No 3 10 Men: 6/9 = 66.7%; Women: 5/15 = 33.3%; a greater percentage of men reported driving over 100 mph. 1.63 Answers will vary. Students should not copy the words they see in these answers. Randomly divide the group in half, using a coin flip for each woman: Heads she gets the vitamin D, and tails she gets the placebo (or vice versa). Make sure that neither the women themselves nor any of the people who come in contact with them know whether they got the treatment or the placebo (“double-blind”). Over a given length of time (such as three years), note which women had broken bones and which did not. Compare the percentage of women with broken bones in the vitamin D group with the percentage of women with broken bones in the placebo group. Copyright © 2020 Pearson Education, Inc. 8 Introductory Statistics: Exploring the World Through Data, 3rd edition 1.64 Answers will vary. Students should not copy the words they see here. Randomly divide the group in half, using a coin flip for each person: Heads they get Coumadin, and tails they get aspirin (or vice versa). Make sure that neither the subjects nor any of the people who come in contact with them know which treatment they received (“double-blind”). Over a given length of time (such as three years), note which people had second strokes and which did not. Compare the percentage of people with second strokes in the Coumadin group with the percentage of people with second strokes in the aspirin group. There is no need for a placebo because we are comparing two treatments. However, it would be acceptable to have three groups, one of which received a placebo. 1.65 a. The treatment variable is mindful yoga participation. The response variable is alcohol use. b. Controlled experiment (random assignment to treatment/control groups). c. No, since the sample size was fairly small; however, the difference in outcomes for treatment/control groups may indicate that further research into the use of mindful yoga may be warranted. 1.66 a. The treatment variable was neurofeedback; the response variable is ADHD symptoms. b. Controlled experiment (random assignment to treatment/control groups). c. No because there were no significant differences in outcomes between any of the groups. 1.67 No. There was no control group and no random assignment to treatment or control groups. 1.68 a. Long course antibiotics: 39/238 = 16.4%; short course antibiotics: 77/229 = 33.6%. The longer course recipients did better. b. 10 days 5 days Failure 39 77 Success 199 152 c. Controlled experiment (random assignment to treatment/control groups). d. Yes. This was a controlled, randomized experiment with a large sample size. 1.69 a. LD: 8% tumors; LL: 28% tumors A greater percentage of the 24 hours of light developed tumors. b. A controlled experiment. You can tell by the random assignment. c. Yes, we can conclude cause and effect because it was a controlled experiment, and random assignment will balance out potential confounding variables. 1.70 a. b. 43/53, or about 81.1%, of the males who were assigned to Scared Straight we rearrested. 37/55, or 67.3%, of those receiving no treatment were rearrested So the group from Scared Straight had a higher arrest rate. No, Scared Straight does not cause a lower arrest rate because the arrest rate was higher. Copyright © 2020 Pearson Education, Inc. Chapter 2: Picturing Variation with Graphs Section 2.1: Visualizing Variation in Numerical Data and Section 2.2: Summarizing Important Features of a Numerical Distribution 2.1 2.2 a. 4 people had resting pulse rates more than 100. b. 4  3.2% of the people had resting pulse rates of more than 100. 125 a. 8 people have glucose readings above 120 mg/dl. b. 8  6.1% of these people have glucose readings above 120 mg/dl. 5 1 2 3 4  0.20  0.04,  0.08,  0.12,  0.16, 25 25 25 25 25 2.3 New vertical axis labels: 2.4 a. The bin width is 100. b. The histogram is bimodal because two bins have a much higher relative frequency than the others. c. About 19% (combine 6% and 13%). Due to the scale on the graph, any answer between 18% to 20% is acceptable. 2.5 Yes, since only about 7% of the pulse rates were higher than 90 bpm. Conclusion might vary, but students must mention that 7% of pulse rates were higher than 90 bpm. 2.6 No, because on roughly half of the days the post office served more than 250 customers, so 250 would not be unusual. 2.7 a. Both cereals have similar center values (about 110 calories). The spread of the dotplots differ. b. Cereal from manufacturer K tend to have more variation. a. Both distributions have more than one mode. The center for the coins from the United States is much larger than the center for other countries. The spreads are similar. b. Coins in the United States tend to weigh more, as we conclude because the center of the distribution is higher for the United States coins. 2.8 2.9 Roughly bell shaped. The lower bound is 0, the mean will be a number probably below 9, but a few students might have slept quite a bit (up to 12 hours?) which creates a right-skew. 2.10 Roughly right-skewed (most students with no tickets, very few with many tickets). 2.11 It would be bimodal because the men and women tend to have different heights and therefore different arm spans. 2.12 It might be bimodal because private colleges and public colleges tend to differ in amount of tuition. 2.13 About 75 beats per minute. 2.14 About 500 Calories. 2.15 The BMI for both groups are right skewed. For the men it is maybe bimodal (hard to tell). The typical values for the men and women are similar although the value for the men appears just a little bit larger than the typical value for the women. The women’s values are more spread out. 2.16 a. b. Both distributions are right skewed. They have similar typical values. The men’s distribution is more spread out and has a greater percentage of values that are considered high. So, the women’s levels are somewhat better. Copyright © 2020 Pearson Education, Inc. 9 10 Introductory Statistics: Exploring the World Through Data, 3rd edition 2.17 a. The distribution is multimodal with modes at 12 years (high school), 14 years (junior college), 16 years (bachelor’s degree), and 18 years (possible master’s degree). It is also left-skewed with numbers as low as 0. b. Estimate: 300 + 50 + 100 + 40 + 50, or about 500 to 600, had 16 or more years. c. Between 2.18 a. 500 600 , or about 25%, and , or about 30%, have a bachelor’s degree or higher. This is very 2018 2018 similar to the 27% given. The distribution is right-skewed. b. About 2 or 3. c. Between 80 and 100. d. 80 100  4% or  5% 2000 2000 2.19 Ford typically has higher monthly costs (the center is near 250 dollars compared with 225 for BMW) and more variation in monthly costs. 2.20 Both makes have similar typical mpg (around 23 mpg). BMW has more variation in mpg (more horizontal spread in the data). 2.21 1. The assessed values of homes would tend to be lower with a few higher values: This is histogram B. 2. The number of bedrooms in the houses would be slightly skewed right: This is histogram A. 3. The height of house (in stories) for a region would be that allows up to 3 stories would be histogram C. 2.22 1. The consumption of coffee by a person would be skewed right with many people who do not drink coffee and a few who drink a lot: This is histogram A. 2. The maximum speed driven in a car would be roughly symmetrical with a few students who drive very fast: This is histogram C. 3. The number of times a college student had breakfast would skew left with students who rarely eat breakfast: This is histogram B. 2.23 1. The heights of students would be bimodal and roughly symmetrical: This is histogram B. 2. The number of hours of sleep would be unimodal and roughly symmetrical, with any outliers more likely being fewer hours of sleep: This is histogram A. 3. The number of accidents would be left skewed, with most student being involved in no or a few accidents: This is histogram C. 2.24 1. The SAT scores would be unimodal and roughly symmetrical: This is histogram C. 2. The weights of men and women would be bimodal and roughly symmetrical, but with more variation that SAT scores: This is histogram A. 3. The ages of students would be left skewed, with most student being younger: This is histogram B. 2.25 Students should display a pair of dotplots or histograms. One graph for Hockey and one for Soccer. The hockey team tends to be heavier than the soccer team (the typical hockey player weighs about 202 pounds while the typical soccer player weighs about 170 pounds). The soccer team has more variation in weights than the hockey team because there is more horizontal spread in the data. Statistical Question (answers may vary): Are hockey players heavier than soccer players? Which type of athlete has the most variability in weight? Copyright © 2020 Pearson Education, Inc. Chapter 2: Picturing Variation with Graphs 11 2.26 (Answers may vary). Which type of apartment tends to cost more? See histograms. Studio apartments tend to be less expensive and have more variation in price than do one-bedrooms. 2.27 See histogram. The shape will depend on the binning used. The histogram is bimodal with modes at about $30 and about $90. Output for Exercise 27 12 Frequency 10 8 6 4 2 0 30 60 90 Cost (dollars) 120 2.28 See histogram. The shape will depend on the binning used. The 800 score could be an outlier or not, and the graph could appear left-skewed or not. Output for Exercise 28 14 12 Frequency 10 8 6 4 2 0 480 560 640 720 SAT Score 800 Copyright © 2020 Pearson Education, Inc. 12 Introductory Statistics: Exploring the World Through Data, 3rd edition 2.29 See histogram. The histogram is right-skewed. The typical value is around 12 (between 10 and 15) years, and there are three outliers: Asian elephant (40 years), African elephant (35 years), and hippo (41 years). Humans (75 years) would be way off to the right; they live much longer than other mammals. Output for Exercise 29 14 Frequency 12 10 8 6 4 2 0 5 10 15 20 25 30 35 40 Average Longevity (years) 2.30 The histogram is right-skewed and also bimodal (at least with this grouping). The modes are at about 80 days and 240 days. The typical value is about 240 days (between 160 and 320 days). There are two outliers at more than 600 days, the Asian elephant and the African elephant. Humans (266 days) would be near the middle of the graph. Output for Exercise 30 12 Frequency 10 8 6 4 2 0 80 160 240 320 400 480 560 640 Gestation Period (days) 2.31 Both graphs are multimodal and right-skewed. The Democrats have a higher typical value, as shown by the fact that the center is roughly around 35 or 40%, while the center value for the Republicans is closer to 20 to 30%. Also note the much larger proportion of Democrats who think the rate should be 50% or higher. The distribution for the Democrats appears more spread out because the Democrats have more people responding with both lower and higher percentages. Output for Exercise 31 Democrat Republican 0 15 30 45 60 75 90 Ideal Maxim um Tax Rate (percentage) E ach sy mbol represents up to 2 observ ations. Copyright © 2020 Pearson Education, Inc. Chapter 2: Picturing Variation with Graphs 13 2.32 Both distributions are right-skewed. A large outlier did represent a cat lover, but typically, cat lovers and dog lovers both seem to have about 2 pets, although there are a whole lot of dog lovers with one dog. Output for Exercise 32 C at Dog 0 2 4 6 8 10 Num ber of Pets 12 14 E ach sy mbol represents up to 2 observ ations. 2.33 The distribution appears left-skewed because of the low-end outlier at about $20,000 (Brigham Young University). Output for Exercise 33 14 12 Frequency 10 8 6 4 2 0 20 25 30 35 40 45 50 55 Tuition (thousands of dollars) 2.34 The histogram is strongly right-skewed, with outliers. Output for Exercise 34 70 Frequency 60 50 40 30 20 10 0 0 40 80 120 160 200 240 280 Text Messages Sent in One Day Copyright © 2020 Pearson Education, Inc. 14 Introductory Statistics: Exploring the World Through Data, 3rd edition 2.35 With this grouping the distribution appears bimodal with modes at about 110 and 150 calories. (With fewer— that is, wider—bins, it may not appear bimodal.) There is a low-end outlier at about 70 calories. There is a bit of left skew. Output for Exercise 35 25 Frequency 20 15 10 5 0 80 100 120 140 160 180 200 Calories in 12 Ounces of Beer 2.36 The distribution is left-skewed primarily because of the outliers at about 0% alcohol. Output for Exercise 36 30 Frequency 25 20 15 10 5 0 0 1 2 3 4 5 6 Percent Alcohol in Beer Section 2.3: Visualizing Variation in Categorical Variables and Section 2.4: Summarizing Categorical Distributions 2.37 No, the largest category is Wrong to Right, which suggests that changes tend to make the answers more likely to be right. 2.38 a. About 7.5 million. b. About 5 million. c. No, overweight and obesity do not result in the highest rate. That is from high blood pressure. d. This is a Pareto chart. 2.39 A bar graph with the least variability would be one in which most children favored one particular flavor (like chocolate). A bar graph with most variability, would be one in which children were roughly equally split in their preference. with 1/3 choosing vanilla, 1/3 chocolate, 1/3 strawberry. 2.40 Least amount of variability would be one where most of the applicants had the same education goal (like transfer). Most variability would be one where applicants were roughly equally divided among the five choices. Copyright © 2020 Pearson Education, Inc.