Chapter 14 Resource Masters New York, New York Columbus, Ohio Woodland Hills, California Peoria, Illinois StudentWorksTM This CD-ROM includes the entire Student Edition along with the Study Guide, Practice, and Enrichment masters. TeacherWorksTM All of the materials found in this booklet are included for viewing and printing in the Advanced Mathematical Concepts TeacherWorks CD-ROM. Copyright © The McGraw-Hill Companies, Inc. All rights reserved. Printed in the United States of America. Permission is granted to reproduce the material contained herein on the condition that such material be reproduced only for classroom use; be provided to students, teachers, and families without charge; and be used solely in conjunction with Glencoe Advanced Mathematical Concepts. Any other reproduction, for use or sale, is prohibited without prior written permission of the publisher. Send all inquiries to: Glencoe/McGraw-Hill 8787 Orion Place Columbus, OH 43240-4027 ISBN: 0-07-869141-9 1 2 3 4 5 6 7 8 9 10 Advanced Mathematical Concepts Chapter 14 Resource Masters XXX 11 10 09 08 07 06 05 04 Contents Vocabulary Builder . . . . . . . . . . . . . . . . . vii-x Chapter 14 Assessment Chapter 14 Test, Form 1A . . . . . . . . . . . 625-626 Chapter 14 Test, Form 1B . . . . . . . . . . . 627-628 Chapter 14 Test, Form 1C . . . . . . . . . . . 629-630 Chapter 14 Test, Form 2A . . . . . . . . . . . 631-632 Chapter 14 Test, Form 2B . . . . . . . . . . . 633-634 Chapter 14 Test, Form 2C . . . . . . . . . . . 635-636 Chapter 14 Extended Response Assessment . . . . . . . . . . . . . . . . . . . . . . . 637 Chapter 14 Mid-Chapter Test . . . . . . . . . . . . 638 Chapter 14 Quizzes A & B . . . . . . . . . . . . . . 639 Chapter 14 Quizzes C & D. . . . . . . . . . . . . . 640 Chapter 14 SAT and ACT Practice . . . . 641-642 Chapter 14 Cumulative Review . . . . . . . . . . 643 Unit 4 Review . . . . . . . . . . . . . . . . . . . . 645-646 Unit 4 Test . . . . . . . . . . . . . . . . . . . . . . . 647-650 Lesson 14-1 Study Guide . . . . . . . . . . . . . . . . . . . . . . . . . 609 Practice . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 610 Enrichment . . . . . . . . . . . . . . . . . . . . . . . . . . 611 Lesson 14-2 Study Guide . . . . . . . . . . . . . . . . . . . . . . . . . 612 Practice . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 613 Enrichment . . . . . . . . . . . . . . . . . . . . . . . . . . 614 Lesson 14-3 Study Guide . . . . . . . . . . . . . . . . . . . . . . . . . 615 Practice . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 616 Enrichment . . . . . . . . . . . . . . . . . . . . . . . . . . 617 Lesson 14-4 Study Guide . . . . . . . . . . . . . . . . . . . . . . . . . 618 Practice . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 619 Enrichment . . . . . . . . . . . . . . . . . . . . . . . . . . 620 SAT and ACT Practice Answer Sheet, 10 Questions . . . . . . . . . . . . . . . . . . . . . . . A1 SAT and ACT Practice Answer Sheet, 20 Questions . . . . . . . . . . . . . . . . . . . . . . . A2 ANSWERS . . . . . . . . . . . . . . . . . . . . . . A3-A16 Lesson 14-5 Study Guide . . . . . . . . . . . . . . . . . . . . . . . . . 621 Practice . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 622 Enrichment . . . . . . . . . . . . . . . . . . . . . . . . . . 623 © Glencoe/McGraw-Hill iii Advanced Mathematical Concepts A Teacher’s Guide to Using the Chapter 14 Resource Masters The Fast File Chapter Resource system allows you to conveniently file the resources you use most often. The Chapter 14 Resource Masters include the core materials needed for Chapter 14. These materials include worksheets, extensions, and assessment options. The answers for these pages appear at the back of this booklet. All of the materials found in this booklet are included for viewing and printing in the Advanced Mathematical Concepts TeacherWorks CD-ROM. Vocabulary Builder Pages vii-x include a Practice There is one master for each lesson. student study tool that presents the key vocabulary terms from the chapter. Students are to record definitions and/or examples for each term. You may suggest that students highlight or star the terms with which they are not familiar. These problems more closely follow the structure of the Practice section of the Student Edition exercises. These exercises are of average difficulty. When to Use These provide additional practice options or may be used as homework for second day teaching of the lesson. When to Use Give these pages to students before beginning Lesson 14-1. Remind them to add definitions and examples as they complete each lesson. Enrichment There is one master for each lesson. These activities may extend the concepts in the lesson, offer a historical or multicultural look at the concepts, or widen students’ perspectives on the mathematics they are learning. These are not written exclusively for honors students, but are accessible for use with all levels of students. Study Guide There is one Study Guide master for each lesson. When to Use Use these masters as reteaching activities for students who need additional reinforcement. These pages can also be used in conjunction with the Student Edition as an instructional tool for those students who have been absent. © Glencoe/McGraw-Hill When to Use These may be used as extra credit, short-term projects, or as activities for days when class periods are shortened. iv Advanced Mathematical Concepts Assessment Options Intermediate Assessment The assessment section of the Chapter 14 Resources Masters offers a wide range of assessment tools for intermediate and final assessment. The following lists describe each assessment master and its intended use. Chapter Tests • Forms 1A, 1B, and 1C Form 1 tests contain multiple-choice questions. Form 1A is intended for use with honors-level students, Form 1B is intended for use with averagelevel students, and Form 1C is intended for use with basic-level students. These tests are similar in format to offer comparable testing situations. Forms 2A, 2B, and 2C Form 2 tests are composed of free-response questions. Form 2A is intended for use with honors-level students, Form 2B is intended for use with average-level students, and Form 2C is intended for use with basic-level students. These tests are similar in format to offer comparable testing situations. The Extended Response Assessment includes performance assessment tasks that are suitable for all students. A scoring rubric is included for evaluation guidelines. Sample answers are provided for assessment. © Glencoe/McGraw-Hill • Four free-response quizzes are included to offer assessment at appropriate intervals in the chapter. • The SAT and ACT Practice offers continuing review of concepts in various formats, which may appear on standardized tests that they may encounter. This practice includes multiple-choice, quantitativecomparison, and grid-in questions. Bubblein and grid-in answer sections are provided on the master. • The Cumulative Review provides students an opportunity to reinforce and retain skills as they proceed through their study of advanced mathematics. It can also be used as a test. The master includes free-response questions. Answers All of the above tests include a challenging Bonus question. • A Mid-Chapter Test provides an option to assess the first half of the chapter. It is composed of free-response questions. Continuing Assessment Chapter Assessments • • v • Page A1 is an answer sheet for the SAT and ACT Practice questions that appear in the Student Edition on page 939. Page A2 is an answer sheet for the SAT and ACT Practice master. These improve students’ familiarity with the answer formats they may encounter in test taking. • The answers for the lesson-by-lesson masters are provided as reduced pages with answers appearing in red. • Full-size answer keys are provided for the assessment options in this booklet. Advanced Mathematical Concepts Chapter 14 Leveled Worksheets Glencoe’s leveled worksheets are helpful for meeting the needs of every student in a variety of ways. These worksheets, many of which are found in the FAST FILE Chapter Resource Masters, are shown in the chart below. • Study Guide masters provide worked-out examples as well as practice problems. • Each chapter’s Vocabulary Builder master provides students the opportunity to write out key concepts and definitions in their own words. • Practice masters provide average-level problems for students who are moving at a regular pace. • Enrichment masters offer students the opportunity to extend their learning. Five Different Options to Meet the Needs of Every Student in a Variety of Ways primarily skills primarily concepts primarily applications BASIC AVERAGE 1 Study Guide 2 Vocabulary Builder 3 Parent and Student Study Guide (online) © Glencoe/McGraw-Hill 4 Practice 5 Enrichment vi ADVANCED Advanced Mathematical Concepts NAME _____________________________ DATE _______________ PERIOD ________ Chapter 14 Reading to Learn Mathematics Vocabulary Builder This is an alphabetical list of the key vocabulary terms you will learn in Chapter 14. As you study the chapter, complete each term’s definition or description. Remember to add the page number where you found the term. Vocabulary Term Found on Page Definition/Description/Example arithmetic mean back-to-back bar graph bar graph bimodal box-and-whisker plot class interval class limit class mark cumulative frequency distribution frequency distribution (continued on the next page) © Glencoe/McGraw-Hill vii Advanced Mathematical Concepts NAME _____________________________ DATE _______________ PERIOD ________ Chapter 14 Reading to Learn Mathematics Vocabulary Builder (continued) Vocabulary Term Found on Page Definition/Description/Example frequency polygon hinge histogram inferential statistics interquartile range leaf level of confidence line plot mean mean deviation measure of central tendency (continued on the next page) © Glencoe/McGraw-Hill viii Advanced Mathematical Concepts NAME _____________________________ DATE _______________ PERIOD ________ Chapter 14 Reading to Learn Mathematics Vocabulary Builder (continued) Vocabulary Term Found on Page Definition/Description/Example measure of variability median median class mode normal curve normal distribution outlier percentile population quartile random sample (continued on the next page) © Glencoe/McGraw-Hill ix Advanced Mathematical Concepts NAME _____________________________ DATE _______________ PERIOD ________ Chapter Reading to Learn Mathematics 14 Vocabulary Builder (continued) Vocabulary Term Found on Page Definition/Description/Example range semi-interquartile range standard deviation standard error of the mean stem stem-and-leaf plot three-dimensional bar graph variance whisker © Glencoe/McGraw-Hill x Advanced Mathematical Concepts NAME _____________________________ DATE _______________ PERIOD ________ 14-1 Study Guide The Frequency Distribution A frequency distribution is a convenient system for organizing large amounts of data. A number of classes are determined, and all values in a class are tallied and grouped together. The most common way of displaying frequency distributions is by using a type of bar graph called a histogram. Example The number of passengers who boarded planes at 36 airports in the United States in one year are shown below. 30,526 30,372 26,623 22,722 16,287 15,246 14,807 14,117 14,054 13,547 12,916 12,616 11,906 11,622 11,489 10,828 10,653 10,008 9703 9594 9463 9348 9125 8572 7300 6772 6549 6126 5907 5712 5287 4848 4832 4820 4750 4684 Source: U.S. Department of Transportation a. Find the range of the data. The range of the data is 30,526 4684 or 25,842. b. Determine an appropriate class interval. An appropriate class interval is 4500 passengers, beginning with 4500 and ending with 31,500. There will be six classes. c. Name the class limits and the class marks. The class limits are the upper and lower values in each interval, or 4500, 9000, 13,500, 18,000, 22,500, 27,000, and 31,500. The class marks are the averages of the class limits of each interval, or 6750, 11,250, 15,750, 20,250, 24,750, and 29,250. d. Construct a frequency distribution of the data. Use tallies to determine the number of passengers in each interval. Number of Passengers Tallies Frequency 4500-9000 13 9000-13,500 13 13,500-18,000 6 18,000-22,500 0 22,500-27,000 2 27,000-31,500 2 e. Draw a histogram of the data. Label the horizontal axis with the class limits. The vertical axis should be labeled from 0 to a value that will allow for the greatest frequency. Draw the bars side by side so that the height of each bar corresponds to its interval’s frequency. © Glencoe/McGraw-Hill 609 Advanced Mathematical Concepts NAME _____________________________ DATE _______________ PERIOD ________ 14-1 Practice The Frequency Distribution Determine which class intervals would be appropriate for the data below. Explain your answers. 1. 25, 32, 18, 99, 43, 16, 29, 35, 36, 34, 21, 33, 26, 26, 17, 40, 22, 38, 16, 19 a. 1 b. 10 c. 2 2. 111, 115, 130, 200, 234, 98, 115, 72 305, 145, 87, 63, 245, 285, 256, 302 a. 25 b. 10 c. 30 3. Meteorology The average wind speeds recorded at various weather stations in the United States are listed below. Station Speed (mph) Albuquerque Baltimore Station 8.9 Anchorage 9.1 Speed (mph) Station Speed (mph) 7.1 Atlanta 9.1 10.4 Boston 12.5 Chicago Dallas-Ft. Worth 10.8 Honolulu 11.3 Indianapolis 9.6 Kansas City 10.7 Las Vegas 9.3 Little Rock 7.8 Los Angeles 6.2 Memphis 8.8 Miami 9.2 Minneapolis– St. Paul 10.5 Philadelphia 9.5 New Orleans 8.1 New York City 9.4 Phoenix 6.2 Seattle 9.0 Source: National Climatic Data Center a. Find the range of the data. b. Determine an appropriate class interval. c. What are the class limits and the class marks? d. Construct a frequency distribution of the data. e. Draw a histogram of the data. e. © Glencoe/McGraw-Hill 610 Advanced Mathematical Concepts NAME _____________________________ DATE _______________ PERIOD ________ 14-1 Enrichment Misuses of Statistics Statistics can be misleading. Two graphs for the same set of data can look very different from each other. Compare the following graphs. Notice that the two graphs show the same data, but the spacing in the vertical and horizontal scales differs. Scales can be cramped or spread out to make a graph that gives a certain impression. 1. Which graph would you use to give the impression that the unemployment rate dropped dramatically from 1982 to 1990? 2. Suppose that a car company claims, “75% of people surveyed say that our car is better than the competition.” If only four people were surveyed, how many people thought that this company’s car was better? Suppose an advertiser claims that 90% of all the cars of one brand sold in the last 10 years are still on the road. 3. If 10,000 cars were sold, how many are still on the road? 4. If 1000 cars were sold, how many are still on the road? 5. Find an example to show how you think averages could be used in a misleading way. 6. A survey of a large sample of people who own small computers revealed that 85% of the people thought the instruction manuals should be better written. A manufacturer of small computers claimed that it surveyed many of the same people and found that all of them liked their manuals. Discuss the possible discrepancy in the results. © Glencoe/McGraw-Hill 611 Advanced Mathematical Concepts NAME _____________________________ DATE _______________ PERIOD ________ 14-2 Study Guide Measures of Central Tendency The mean is found by adding the values in a set of data and dividing the sum by the number of values in that set. In other words, if a set of data has n values given by Xi such that i is an integer and 1 i n, then the arithmetic mean X can be found as follows. n X n1 Xi i=1 The median of a set of data is the middle value. If there are two middle values, the median is the mean of the two middle values. The mode of a set of data is the most frequent value. Some sets have multiple modes, and others have no mode. Example 1 Find the mean of the set {13, 18, 21, 14, 16, 19, 25, 17}. sum of the values in the set of data X number of values in the set 13 + 18 + 21 + 14 + 16 + 19 + 25 + 17 X 8 14 3 or 17.875 X 8 The mean of the set of data is 17.875. Example 2 The table at the right shows the number of households without a telephone in 1990. a. Find the mean of the data. Since there are 11 states listed in the table, n 11. 11 Xi 111 (131,600 313,100 270,200 1 11i=1 195,700 36,500 140,900 40,400 25,100 67,500 106,400 70,800) The mean is about 127,109. b. Find the median of the data. To find the median, order the data. Since all the numbers are multiples of 100, you can order the set by hundreds. State Alaska Number of Households 131,600 California 313,100 Florida 270,200 Georgia 195,700 Iowa 36,500 Kentucky 140,900 Minnesota 40,400 Nevada 25,100 New Mexico 67,500 Oklahoma 106,400 West Virginia 70,800 Source: U.S. Census Bureau 251 365 404 675 708 1064 1316 1409 1957 2702 3131 Since there are an odd number of values, the median is the middle value, or 106,400. c. Find the mode of the data. Since all elements in the set of data have the same frequency, there is no mode. © Glencoe/McGraw-Hill 612 Advanced Mathematical Concepts NAME _____________________________ DATE _______________ PERIOD ________ 14-2 Practice Measures of Central Tendency Find the mean, median, and mode of each set of data. 1. {15, 42, 26, 39, 93, 42} 2. {32, 12, 61, 94, 73, 62, 94, 35, 44, 52} 3. {152, 697, 202, 312, 109, 134, 116} 4. {18, 6, 22, 33, 19, 34, 14, 54, 12, 22, 19} 5. A shoe store employee sets up a display by placing shoeboxes in 10 stacks. The numbers of boxes in each stack are 5, 7, 9, 11, 13, 10, 9, 8, 7, and 5. a. What is the mean of the number of boxes in a stack? b. Find the median of the number of boxes in a stack. c. If one box is removed from each stack, how will the mean and median be affected? Find the mean, median, and mode of the data represented by each stem-and-leaf plot. 6. Stem Leaf 2 2 4 4 7 3 1 3 4 4 5 6 8 5 9 2/2 220 7. Stem Leaf 9 0113 10 1 3 5 6 11 3 4 6 8 9/0 90 9. Medicine A frequency distribution for the number of patients treated at 50 U.S. cancer centers in one year is given at the right. a. Use the frequency chart to find the mean of the number of patients treated by a cancer center. b. What is the median class of the frequency distribution? 8. Stem Leaf 1 1 2 9 2 3 3 5 3 2 4 0 5 4 5 6 8 9 1/1 1.1 Patients Number of Cancer Centers 500–1000 26 1000–1500 14 1500–2000 6 2000–2500 0 2500–3000 2 3000–3500 0 3500–4000 2 Source: U.S. News Online © Glencoe/McGraw-Hill 613 Advanced Mathematical Concepts NAME _____________________________ DATE _______________ PERIOD ________ 14-2 Enrichment The Harmonic Mean The harmonic mean H is a useful measure of central tendency in special cases of averaging rates. Example Recently Kendra and Bill took a trip of 370 miles and shared the driving. Kendra drove two hours at a rate of 30 mph and then drove the next 110 miles on a freeway at 55 mph. Then Bill drove the next two hours at 50 mph and he drove the last 100 miles on a freeway at 55 mph. What was the average speed of each driver? Kendra drove the same length of time on both portions of her driving, so her average speed is the mean of the two rates. Her average speed was 30 55 2 or 42.5 mph. On the other hand, Bill drove the same distance on both portions of his driving, but the two lengths of time varied. Actually, the time he drove was 100 50 100 , 55 or approximately 3.82 hours. His average speed was 200 , 3.82 or about 52.4 mph. Bill’s average speed also may be found by using the formula for the harmonic mean as follows. Let n number of rates xi where 1 i n. H n n 1 __ xi i1 We apply the formula to Bill’s speeds. 2 H ______ 1 1 50 55 H 52.4 mph The mean, also called the arithmetic mean, is used when equal times are involved. When equal distances are involved, the harmonic mean is used. Find the harmonic mean of each set of data. Round each answer to the nearest hundreth. 1. {3, 4, 5, 6} 2. {5, 10, 15, 20, 25} 3. Bev, Phyllis, and Gordon competed in a 375-mile relay race. Bev drove 40 mph, Phyllis drove 50 mph, and Gordon drove 60 mph. If each drove 125 miles, find the average driving speed of the contestants. © Glencoe/McGraw-Hill 614 Advanced Mathematical Concepts NAME _____________________________ DATE _______________ PERIOD ________ 14-3 Study Guide Measures of Variability If a set of data has been arranged in order and the median is found, the set of data is divided into two groups. If the median of each group is found, the data is divided into four groups. Each of these groups is called a quartile, and the quartile points Q1, Q2, and Q3 denote the breaks for each quartile. The interquartile range is the difference between the first quartile point and the third quartile point. Example 1 Month The table shows the average monthly temperatures for San Diego in 1997. a. Find the interquartile range of the temperatures and state what it represents. First, order the data from least to greatest and identify Q1, Q2, and Q3. 57.4 57.9 58.0 61.6 62.5 64.0 67.4 68.7 68.7 69.3 72.9 75.5 For this set of data, the quartile points Q1, Q2, and Q3 are not members of the set. Instead, Q2 is the mean of the middle values of the set. Thus, Q1 59.8, Q2 65.7, and Q3 69.0. The interquartile range is 69.0 59.8, or 9.2. This means that half the average monthly temperatures are within 9.2F of each other. b. Find the semi-interquartile range of the temperatures. 9.2 , or 4.6. The semi-interquartile range is 2 Example 2 Temperature (°F) Jan. 58.0 Feb. 57.9 March 61.6 April 62.5 May 68.7 June 67.4 July 69.3 Aug. 72.9 Sept. 75.5 Oct. 68.7 Nov. 64.0 Dec. 57.4 Source: National Climatic Data Center Find the mean deviation of the temperatures in Example 1. There are 12 temperatures listed, and the mean is 112 Xi, or 65.325. MD 112 Xi 65.325 MD n1 Xi X MD 112(75.5 65.325 72.9 65.325 . . . 57.4 65.325) MD 112(10.175 7.575 . . . 7.925) or about 5.092 The mean deviation of the temperatures is about 5.092. This means that the temperatures are an average of about 5.092F above or below the mean temperature of 65.325F. © Glencoe/McGraw-Hill 615 Advanced Mathematical Concepts NAME _____________________________ DATE _______________ PERIOD ________ 14-3 Practice Measures of Variability Find the interquartile range and the semi-interquartile range of each set of data. Then draw a box-and-whisker plot. 1. 43, 26, 92, 11, 8, 49, 52, 126, 86, 42, 63, 78, 91, 79, 86 2. 1.6, 9.8, 4.5, 6.2, 8.7, 5.6, 3.9, 6.8, 9.7, 1.1, 4.7, 3.8, 7.5, 2.8, 0.1 Find the mean deviation and the standard deviation of each set of data. 3. 146, 289, 121, 146, 212, 98, 86, 153, 128, 136, 181, 142 4. 1592, 1486, 1479, 1682, 1720, 1104, 1486, 1895, 1890, 2687, 2450 5. Sociology The frequency distribution at the right shows the average life expectancy for males and females in 15 European Union countries in 1994. a. Find the mean of the female life expectancy. b. Find the mean of the male life expectancy. c. What is the standard deviation of the female life expectancy? Life Expectancy (years) Male Female 71.573.0 3 0 73.074.5 9 0 74.576.0 2 0 76.077.5 1 0 77.579.0 0 3 79.080.5 0 8 80.582.0 0 4 Frequency Source: Department of Health and Children, Ireland d. What is the standard deviation of the male life expectancy? © Glencoe/McGraw-Hill 616 Advanced Mathematical Concepts NAME _____________________________ DATE _______________ PERIOD ________ 14-3 Enrichment Percentiles The table at the right shows test scores and their frequencies. The frequency is the number of people who had a particular score. The cumulative frequency is the total frequency up to that point, starting at the lowest score and adding up. Example 1 What score is at the 16th percentile? A score at the 16th percentile means the score just above the lowest 16% of the scores. 16% of the 50 scores is 8 scores. The 8th score is 55. The score just above this is 56. Thus, the score at the 16th percentile is 56. Score Frequency Cumulative Frequency 95 1 50 90 2 49 85 5 47 80 6 42 75 7 36 70 8 29 65 7 21 60 6 14 55 4 8 50 3 4 45 1 1 Notice that no one had a score of 56 points. Use the table above to find the score at each percentile. 1. 42nd percentile ______ 2. 70th percentile ______ 3. 33rd percentile ______ 4. 90th percentile ______ 5. 58th percentile ______ 6. 80th percentile ______ Example 2 At what percentile is a score of 75? There are 29 scores below 75. Seven scores are at 75. The fourth of these seven is the midpoint of this group. Adding 4 scores to the 29 gives 33 scores. 33 out of 50 is 66%. Thus, a score of 75 is at the 66th percentile. Use the table above to find the percentile of each score. 7. a score of 50 ______ 8. a score of 77 ______ 9. a score of 85 ______ 10. a score of 58 ______ 11. a score of 62 ______ 12. a score of 81 ______ © Glencoe/McGraw-Hill 617 Advanced Mathematical Concepts NAME _____________________________ DATE _______________ PERIOD ________ 14-4 Study Guide The Normal Distribution A normal distribution is a frequency distribution that often occurs when there is a large number of values in a set of data. The graph of a normal distribution is a symmetric, bell-shaped curve known as a normal curve. The tables below give the fractional parts of a normally distributed set of data for selected areas about the mean. The letter t represents the number of standard deviations from the mean, that is, X t. P represents the fractional part that lies in the interval X t. t P t P t P t P t P t P 0.0 0.000 0.6 0.451 1.2 0.770 1.7 0.911 2.2 0.972 2.7 0.993 0.1 0.080 0.7 0.516 1.3 0.807 1.8 0.929 2.3 0.979 2.8 0.995 0.2 0.159 0.8 0.576 1.4 0.838 1.9 0.943 2.4 0.984 2.9 0.996 0.3 0.236 0.9 0.632 1.5 0.866 1.96 0.950 2.5 0.988 3.0 0.997 0.4 0.311 1.0 0.683 1.6 0.891 2.0 0.955 2.58 0.990 3.5 0.9995 0.5 0.383 1.1 0.729 1.65 0.900 2.1 0.964 2.6 0.991 4.0 0.9999 Example 1 Air passengers traveling through Atlanta have an average layover of 82 minutes with a standard deviation of 7.5 minutes. Sketch a normal curve that represents the frequency of layover times. First, find the values defined by the standard deviation in a normal distribution. 1 82 1(7.5) or 74.5 X 1 82 1(7.5) or 89.5 X 2 82 2(7.5) or 67 X 2 82 2(7.5) or 97 X X 3 82 3(7.5) or 104.5 X 3 82 3(7.5) or 59.5 Then, sketch the general shape of a normal curve. Replace the horizontal scale with the values you have calculated. Example 2 Find the upper and lower limits of an interval about the mean within which 15% of the values of a set of normally distributed data can be found if X 725 and 4. Use the tables above to find the value of t that most closely approximates P 0.15. For t 0.2, P 0.159. Choose t 0.2. Now find the limits. X t 725 0.2(4) X 725, t 0.2, 4 724.2 and 725.8 The interval in which 15% of the data lies is 724.2–725.8. © Glencoe/McGraw-Hill 618 Advanced Mathematical Concepts NAME _____________________________ DATE _______________ PERIOD ________ 14-4 Practice The Normal Distribution A set of 1000 values has a normal distribution. The mean of the data is 120, and the standard deviation is 20. 1. How many values are within one standard deviation of the mean? 2. What percent of the data is between 110 and 130? 3. What percent of the data is between 90 and 110? 4. Find the interval about the mean that includes 90% of the data. 5. Find the interval about the mean that includes 77% of the data. 6. Find the limit below which 90% of the data lie. 7. Dog Breeding The weights of full-grown German shepherds at the City View Kennels are normally distributed. The mean weight is 86 pounds, and the standard deviation is 3 pounds. Skipper, a full-grown German shepard, weighs 79 pounds. a. What percent of the full-grown German shepherds at City View Kennels weigh more than Skipper? b. What percent of the full-grown German shepherds at City View Kennels weigh less than Skipper? © Glencoe/McGraw-Hill 619 Advanced Mathematical Concepts NAME _____________________________ DATE _______________ PERIOD ________ 14-4 Enrichment Shapes of Distribution Curves Graphs of frequency distributions can be described as either symmetric or skewed. In a distribution skewed to the right, there are a larger number of high values. The long “tail” extends to the right. In a distribution skewed to the left, there are a larger number of low values. The long “tail” extends to the left. For each of the following, state whether the distribution is symmetric or skewed. If it is skewed, tell whether it is skewed to the right or to the left. 1. 2. 3. 4. 5. 6. A vertical line along the median divides the area under a frequency curve in half. 7. Where is the median in a symmetric distribution? © Glencoe/McGraw-Hill 8. Where is the median in a skewed distribution? 620 Advanced Mathematical Concepts NAME _____________________________ DATE _______________ PERIOD ________ 14-5 Study Guide Sample Sets of Data In statistics, the word population refers to an entire set of items or individuals in a group. Rarely will 100% of a population be accessible as a source of data. Therefore, researchers usually select a random sample of the population to represent the entire population. Because discrepancies are common in random samples, researchers often take many samples and assume that the sample mean is near its true population mean. The standard deviation of the distribution of the sample means is known as the standard error of the mean. Standard Error of the Mean If a sample of data has N values and is the standard deviation, the standard error of the mean x is x . N Example 1 A sample of data has 4500 values and a standard deviation of 12. What is the standard error of the mean? For the sample, N 4500. Find x. 2 , or about 0.179 x 1 N 5 0 4 0 The standard error of the mean for the set of data is approximately 0.179. Example 2 The daily calorie consumption of people in the United States is normally distributed. A team of nutritionists takes a sample of 250 people and records their daily calorie consumption. From this sample, the average daily calorie consumption is 2150 with a standard deviation of 60 calories per day. Determine the interval about the sample mean that has a 1% level of confidence. A 1% level of confidence means that there is less than a 1% chance that the true mean differs from the sample mean by a certain amount. A 1% level of condifence is given when P 99%. When P 0.99, t 2.58. Find x. x 60 or about 3.795 Find the range. X 2150 2.58(3.795) X 2140.2089 and 2159.7911 2 5 0 Thus, the probability is 99% that the true mean is within the interval of 2140.2089 calories per day to 2159.7911 calories per day. © Glencoe/McGraw-Hill 621 Advanced Mathematical Concepts NAME _____________________________ DATE _______________ PERIOD ________ 14-5 Practice Sample Sets of Data Find the standard error of the mean for each sample. Then find the interval about the sample mean that has a 1% level of confidence and the interval about the sample mean that has a 5% level of confidence. 1. 50, N 100, X 250 2. 4, N 64, X 100 3. 2.6, N 250, X 50 4. 4.3, N 375, X 110 The table below shows a frequency distribution of the time in minutes required for students to wash a car during a car wash fundraiser. The distribution is a random sample of 250 cars. Use the table for Exercises 5-10. Number of Minutes 5 6 7 8 9 10 Frequency 2 4 5 1 8 5 5. What is the mean of the data in the frequency distribution? 6. Find the standard deviation of the data. 7. Find the standard error of the mean. 8. Find the interval about the sample mean such that the probability is 0.90 that the true mean lies within the interval. 9. Find the interval about the sample mean such that the probability is 0.95 that the true mean lies within the interval. 10. Determine the interval about the sample mean that has a 1% level of confidence. © Glencoe/McGraw-Hill 622 Advanced Mathematical Concepts NAME _____________________________ DATE _______________ PERIOD ________ 14-5 Enrichment Binomial Expansion Coefficients The picture at the right shows a device often used to illustrate a normal probability distribution. The device is filled with small steel marbles. The marbles roll past a series of hexagonal obstacles, collecting at the bottom in each of nine columns. It can be shown that the number of paths from A to G is 1, A to J is 1, A to H is 3, and A to I is 3. For example, H can be reached by the way of E. Hence the number of paths to H is the sum of the number of paths to D and the number of paths to E. Likewise the number of paths to any point can be found by adding the number of paths to points diagonally above it. This is precisely the method by which the numbers in Pascal’s triangle are obtained. The numbers in Pascal’s triangle are the coefficients in the expansion of (x y)n where n is any positive integer. Therefore, the probability of a marble falling in any given column is proportional to the coefficient of the corresponding term in the binomial expansion of a power. The power is a whole number equal to the row being considered. For example, in the illustration above the columns are in the eighth row. Thus the probability of a marble falling in the third column is proportional to the coefficient of the third term in the binomial expansion of (x y)8. The figure above at the right has equally-spaced vertical segments whose lengths are proportional to the numbers in the eighth row of Pascal’s triangle. A smooth curve connecting the tops of these segments suggests the probable distribution of marbles in the column. Notice the similarity of this curve to the normal distribution curve. Solve. 1. Draw a smooth curve connecting the tops of the segments whose lengths are proportional to the coefficients in the expansion of (x y)12. 2. A teacher decided to mark 64 tests with the grades A, B, C, D, and F (A highest) in proportion to the coefficients in the expansion of (x y)4. How many tests received each grade? © Glencoe/McGraw-Hill 623 Advanced Mathematical Concepts blank NAME _____________________________ DATE _______________ PERIOD ________ Chapter 14 Chapter 14 Test, Form 1A Write the letter for the correct answer in the blank at the right of each problem. The playing times of 20 songs on a top-hits radio station are recorded in the chart below. Use the chart for Exercises 1-6. Playing Time (minutes:seconds) 3:32 3:24 2:54 3:07 4:52 3:45 2:39 3:09 3:34 3:26 3:35 4:17 4:03 3:52 5:10 4:59 3:07 4:00 3:07 2:56 1. In a stem-and-leaf plot of this data where 332 represents 3:32, which of the following stems has the fewest number of leaves? A. 25 B. 30 C. 45 D. 51 1. ________ 2. In a frequency distribution of this data, how many data values are in the class 3:00–3:30? A. 11 B. 5 C. 6 D. 7 2. ________ 3. In a histogram of this data, which bar would have the greatest height? A. 3:00–3:15 B. 3:15–3:30 C. 3:30–3:45 D. 3:45–4:00 3. ________ 4. What is the mean of the data? A. 3:29 B. 3:48 4. ________ C. 3:67 D. 3:40 5. What is the median of the data? A. 3:55 B. 3:33 C. 3:20 5. ________ D. 3:07 6. What is the mode of the data? A. 3:07 B. 3:33 D. None of these 6. ________ C. 3:40 7. Find the value of x so that the mean of 5x, 32 x, x 9, x is 1. A. 2 B. 12 C. 12 D. 2 7. ________ 8. Find the mean of the data represented by the stem-and-leaf plot at the right. A. 2.2 B. 2.5 C. 2.6 D. 2.7 8. ________ stem leaf 1 0 0 1 4 6 8 8 2 2 2 5 6 7 7 3 0 0 1 5 1|0 1.0 For Exercises 9 and 10, use the frequency distribution below. Amount 0–8 Frequency Amount Frequency 18 24–32 11 8–16 15 32–40 9 16–24 16 40–48 6 9. Estimate the mean of the data. A. 20.07 B. 19.57 C. 20.25 10. Estimate the median of the data. A. 19 B. 18.75 C. 20 © Glencoe/McGraw-Hill 625 9. ________ D. 18.64 10. ________ D. 18.25 Advanced Mathematical Concepts NAME _____________________________ DATE _______________ PERIOD ________ Chapter 14 Chapter 14 Test, Form 1A (continued) For Exercises 11–13, use the data in the table below. Average Monthly Temperatures in New Braunfels, Texas (Fahrenheit degrees) Jan. Feb. Mar. April May June July Aug. Sept. Oct. Nov. Dec. 50.7 54.5 61.7 68.7 75.0 81.3 84.0 84.0 79.0 70.0 59.9 52.7 Source: WorldClimate 11. Find the mean deviation of the temperatures. A. 11.84 B. 12.36 C. 10.47 11. ________ D. 12.15 12. Find the standard deviation of the temperatures. A. 11.84 B. 12.36 C. 10.47 D. 12.15 12. ________ 13. What values are used to create a box-and-whisker plot for the data? A. 50.7, 54.5, 69, 79, 84 B. 50.7, 57.2, 69.35, 80.15, 84 C. 50.7, 54.5, 68.7, 79, 84 D. 50.7, 54.5, 69.35, 79, 84 13. ________ For Exercises 14-16, a set of 750 values has a normal distribution with a mean of 12.5 and a standard deviation of 0.36. 14. What percent of the data is between 12.25 and 12.75? A. 38.3% B. 51.6% C. 20.1% D. 45.1% 14. ________ 15. Find the interval about the mean within which 45% of the data lie. A. 12.28–12.72 B. 12.32–12.68 C. 12.15–12.85 D. 12.49–12.51 15. ________ 16. Find the probability that a value selected at random from this data is between 11.67 and 13.33. A. 98.4% B. 57.6% C. 97.9% D. 83.0% 16. ________ In a random sample of 30 tires of the same type, it is found that the average life span of a tire is 36,200 miles with a standard deviation of 3800 miles. 17. Find the standard error of the mean. 17. ________ A. 126.67 B. 693.78 C. 9.53 D. 587.24 18. Find the interval about the sample mean that has a 1% level of confidence. A. 26,396–46,004 B. 35,506–36,894 C. 33,425–38,975 D. 34,410–37,990 18. ________ 19. Find the interval about the sample mean such that the probability is 0.75 that the mean number lies within the interval. A. 35,402–36,998 B. 31,830–40,570 C. 35,436–36,964 D. 35,367–37,033 19. ________ 20. Find the probability that the mean of the population will be less than 560 miles from the mean of the sample. A. 80.7% B. 57.6% C. 1.3% D. 8.1% 20. ________ Bonus Find the probability that the true mean is between 35,000 and 36,000. A. 67.5% B. 33.75% C. 57.35% D. 83.8% © Glencoe/McGraw-Hill 626 Bonus: ________ Advanced Mathematical Concepts NAME _____________________________ DATE _______________ PERIOD ________ Chapter 14 Chapter 14 Test, Form 1B Write the letter for the correct answer in the blank at the right of each problem. The playing times for 20 movies are recorded in the chart below. Use the chart for Exercises 1–6. Playing Time of Movies (minutes) 102 128 123 132 104 95 109 121 108 124 92 140 117 102 124 115 113 89 111 108 1. In a stem-and-leaf plot of this data where 102 represents 102, which stem has the greatest number of leaves? A. 9 B. 10 C. 11 D. 12 1. ________ 2. In a frequency distribution of this data, how many data values are in the class 130–140? A. 0 B. 1 C. 2 D. 3 2. ________ 3. In a histogram of this data, which bar would have the greatest height? A. 105–110 B. 110–115 C. 115–120 D. 120–125 3. ________ 4. What is the mean of the data? A. 112.85 B. 112 4. ________ C. 110.91 D. 124 5. What is the median of the data? A. 115 B. 113 C. 112 6. What is the mode of the data? A. 102 B. 108 5. ________ D. 111 6. ________ C. 124 D. All of the above 7. Find the value of x so that the mean of {x, x 2, 2x 1, 1.4x} is 6. A. 389 B. 5 C. 8. Find the mean of the data represented by the stem-and-leaf plot at the right. A. 85.5 B. 82.45 C. 86.23 D. 86.38 123 7. ________ D. None of these stem leaf 7 6 7 9 8 0 0 1 3 3 3 5 5 6 6 8 9 0 1 1 1 2 5 6 9 7|6 76 8. ________ For Exercises 9 and 10, use the frequency distribution below. Amount Frequency Amount Frequency 15–20 21 30–35 10 20–25 46 35–40 7 25–30 13 40–45 3 9. Estimate the mean of the data. A. 24.75 B. 24.25 C. 25.25 10. Estimate the median of the data. A. 22.07 B. 23.15 C. 28.15 © Glencoe/McGraw-Hill 627 9. ________ D. 23.25 10. ________ D. 27.93 Advanced Mathematical Concepts NAME _____________________________ DATE _______________ PERIOD ________ Chapter 14 Chapter 14 Test, Form 1B (continued) For Exercises 11–13, use the data in the table below. Numbers of Cars Rented Each Month in the U.S. (thousands) Jan. Feb. Mar. April May June July Aug. Sept. Oct. Nov. Dec. 0.7 0.6 0.9 1.2 1.3 1.5 1.8 1.7 1.1 0.9 0.9 1.2 11. Find the mean deviation of the data. A. 0.5 B. 0.4 C. 0.3 11. ________ D. 0.2 12. Find the standard deviation of the data. A. 0.36 B. 0.43 C. 0.41 D. 0.38 12. ________ 13. What values are used to create a box-and-whisker plot for the data? A. 0.6, 0.9, 1.3, 1.3, 1.8 B. 0.6, 0.9, 1.15, 1.4, 1.8 C. 0.6, 0.9, 1.2, 1.5, 1.8 D. 0.6, 0.9, 1.15, 1.5, 1.8 For Exercises 14–16, a set of 300 values has a normal distribution with a mean of 50 and a standard deviation of 5. 14. What percent of the data is between 45 and 55? A. 38.3% B. 50% C. 68.3% D. 95.5% 13. ________ 14. ________ 15. Find the interval about the mean within which 90% of the data lie. A. 40–60 B. 42.5–57.5 C. 38.75–61.25 D. 41.75–58.25 15. ________ 16. Find the probability that a value selected at random from this data is between 49.5 and 50.5. A. 8% B. 9.2% C. 9.8% D. 7.66% 16. ________ In a random sample of 700 refreshment-dispensing machines, it is found that an average of 8.1 ounces is dispensed with a standard deviation of 0.75 ounce. 17. Find the standard error of the mean. A. 0.0107 B. 0.0011 C. 0.2833 D. 0.0283 17. ________ 18. Find the interval about the sample mean that has a 1% level of confidence. A. 8.045–8.155 B. 8.027–8.173 C. 6.165–10.035 D. 8.053–8.147 18. ________ 19. Find the interval about the sample mean such that the probability is 0.90 that the mean number lies within the interval. A. 8.045–8.155 B. 8.027–8.173 C. 6.165–10.035 D. 8.053–8.147 19. ________ 20. Find the probability that the mean of the population will be less than 0.085 ounce from the mean of the sample. A. 30% B. 99.7% C. 49.9% D. 25% 20. ________ Bonus Find the probability that the true mean is between 8.157 and 8.185. A. 2.1% B. 4.45% C. 0.4% D. 0.2% © Glencoe/McGraw-Hill 628 Bonus: ________ Advanced Mathematical Concepts NAME _____________________________ DATE _______________ PERIOD ________ Chapter 14 Chapter 14 Test, Form 1C Write the letter for the correct answer in the blank at the right of each problem. The number of cars sold by 20 salespeople in one week are recorded in the chart below. Use the chart for Exercises 1-6. Number of Cars 10 7 6 9 7 3 5 6 8 4 8 2 7 5 7 9 11 5 7 10 1. In a frequency distribution of this data, how many data values are in the class 4-6? A. 3 B. 7 C. 4 D. 5 1. ________ 2. In a histogram of this data, which bar would have the greatest height? A. 4–6 B. 6–8 C. 8–10 D. 10–12 2. ________ 3. In a histogram of this data, which bar would have the least height? A. 2–4 B. 4–6 C. 6–8 D. 8–10 3. ________ 4. What is the mean of the data? A. 6.5 B. 6.8 4. ________ C. 7 D. 7.2 5. What is the median of the data? A. 6.8 B. 6 C. 7 5. ________ D. 7.5 6. What is the mode of the data? A. 5 B. 8 D. 7 6. ________ C. 6 7. Find the value of x so that the mean of {x, 2x, 3x, 4x} is 5. D. 2.5 A. 2 B. 2 C. 12 7. ________ 8. Find the mean of the data represented by the stem-and-leaf plot at the right. A. 194 B. 193.8 C. 193 D. 194.2 8. ________ stem leaf 18 5 9 19 1 3 3 5 6 8 8 20 0 18|5 185 For Exercises 9 and 10, use the frequency distribution below. Amount Frequency Amount Frequency $0–$10 15 $30–$40 28 $10–$20 21 $40–$50 20 $20–$30 26 $50–$60 12 9. Estimate the mean of the data. A. $29.34 B. $32.21 C. $34.34 10. Estimate the median of the data. A. $25 B. $29.62 C. $45 © Glencoe/McGraw-Hill 629 9. ________ D. $59.62 10. ________ D. $39.62 Advanced Mathematical Concepts NAME _____________________________ DATE _______________ PERIOD ________ Chapter 14 Chapter 14 Test, Form 1C (continued) For Exercises 11-13, use the data in the table below. Average Rainfall in China Flat, California (inches) Jan. Feb. Mar. April May June July 8.8 6.6 5.9 3.0 2.5 0.9 0.1 Aug. Sept. 0.0 0.6 Oct. Nov. Dec. 3.4 5.9 9.0 Source: WorldClimate 11. Find the mean deviation of the data. A. 3.20 B. 3.89 C. 3.13 11. ________ D. 2.79 12. Find the standard deviation of the data. A. 3.20 B. 3.89 C. 3.13 D. 2.79 12. ________ 13. What values are used to create a box-and-whisker plot for the data? A. 0, 0.6, 3, 5.9, 9 B. 0, 0.9, 3.2, 6.3, 9 C. 0, 0.75, 3.2, 6.25, 9 D. 0, 0.6, 3.2, 5.9, 9 For Exercises 14-16, a set of data has a normal distribution with a mean of 120 and a standard deviation of 10. 14. What percent of the data is between 110 and 130? A. 38.3% B. 50% C. 68.3% D. 95.5% 13. ________ 14. ________ 15. Find the interval about the mean within which 90% of the data lie. A. 94.2–145.8 B. 103.5–136.5 C. 113.68–126.32 D. 100.4–139.6 15. ________ 16. Find the probability that a value selected at random from this data is between 100 and 140. A. 99.9% B. 90% C. 99% D. 95.5% 16. ________ In a random sample of 1000 exams, the average score was 500 points with a standard deviation of 80 points. 17. Find the standard error of the mean. A. 15.81 B. 2.53 C. 3.58 D. 8 17. ________ 18. Find the interval about the sample mean that has a 1% level of confidence. A. 499–501 B. 479–520 C. 495–505 D. 493–507 18. ________ 19. Find the interval about the sample mean such that the probability is 0.90 that the mean number lies within the interval. A. 499–501 B. 495–505 C. 496–504 D. 368–632 19. ________ 20. Find the probability that the mean score of the population will be less than five points from the mean score of the sample. A. 95.5% B. 38.3% C. 98.8% D. 62.5% 20. ________ Bonus Find the probability that the true mean is between 495 and 500. A. 95% B. 47.75% C. 95.5% D. 68.3% © Glencoe/McGraw-Hill 630 Bonus: ________ Advanced Mathematical Concepts NAME _____________________________ DATE _______________ PERIOD ________ Chapter 14 Chapter 14 Test, Form 2A Fifty randomly–selected people going to a science fiction movie were asked their age. The results are recorded in the chart below. Use the chart for Exercises 1-6. Ages of Science-Fiction Moviegoers (years) 17 42 21 78 16 21 31 29 29 16 49 19 81 16 69 69 18 31 22 14 21 75 42 78 18 41 22 16 18 80 42 42 42 16 16 21 19 18 44 18 22 14 49 17 16 18 18 18 17 23 1. List the stems that would be used in a stem-and-leaf plot of the data. 1. __________________ 2. Find the range of the data. 2. __________________ 3. Make a histogram of the data. 3. 4. Find the mean of the data. 4. __________________ 5. Find the median of the data. 5. __________________ 6. Find the mode of the data. 6. __________________ 7. Find the value of x so that the mean of {2x, 13 x, 52 x 3, x 2} is 8. 7. __________________ 8. Find the mean of the data below. stem leaf 51 2 5 6 7 9 52 0 2 3 5 8 8 9 9 53 1 1 4 8. __________________ 51|2 5120 For Exercises 9 and 10, use the frequency distribution below. Class Frequency Class Frequency 600–615 2 675–690 2 615–630 8 690–705 38 630–645 16 705–720 24 645–660 3 720–735 7 660–675 5 735–750 3 9. Estimate the mean of the data. 9. __________________ 10. Estimate the median of the data. 10. __________________ © Glencoe/McGraw-Hill 631 Advanced Mathematical Concepts NAME _____________________________ DATE _______________ PERIOD ________ Chapter 14 Chapter 14 Test, Form 2A (continued) The table below gives the save percentages for some goalies at a certain point in a recent NHL season. Use the table for Exercises 11–13. Save Percentages 0.940 0.937 0.930 0.929 0.926 0.925 0.925 0.923 0.923 0.923 0.921 0.920 0.919 0.918 0.916 0.914 0.911 0.911 0.910 0.910 0.909 0.907 0.907 0.904 0.903 0.903 0.902 0.900 0.898 0.895 11. Find the mean deviation of the percentages. 11. __________________ 12. Find the standard deviation of the percentages. 12. __________________ 13. Make a box-and-whisker plot of the percentages. 13. For Exercises 14 –16, a set of 1000 values has a normal distribution with a mean of 400 and a standard deviation of 30. 14. What percent of the data is between 385 and 415? 14. __________________ 15. Find the interval about the mean within which 60% of the data lie. 15. __________________ 16. Find the probability that a value selected at random from this data is greater than 350. 16. __________________ A random sample of 225 homes showed an average of 5.2 clocks in each home. The standard deviation was 0.8. 17. Find the standard error of the mean. 17. __________________ 18. Find the interval about the sample mean that has a 1% level of confidence. 18. __________________ 19. Find the interval about the sample mean such that the probability is 0.75 that the mean number lies within the interval. 19. __________________ 20. Find the probability that the mean of the population will be less than 0.10 from the mean of the sample. 20. __________________ Bonus Find the probability that the true mean is between 5 and 5.1. © Glencoe/McGraw-Hill 632 Bonus: __________________ Advanced Mathematical Concepts NAME _____________________________ DATE _______________ PERIOD ________ Chapter 14 Chapter 14 Test, Form 2B Fifty students recorded the number of hours that the television was on in their homes during one week. The results are given in the chart below. Use the chart for Exercises 1–6. Weekly Television Hours (to the nearest hour) 54 28 9 15 3 54 35 32 0 34 72 57 62 33 58 23 57 53 24 27 36 63 34 58 53 13 12 75 66 57 18 53 53 46 77 26 32 42 43 88 44 71 22 57 45 73 44 11 45 34 1. List the leaves for stem 1 in a stem-and-leaf plot of the data. 1. __________________ 2. List the class marks for the intervals 0–20, 20–40, 40–60, 60–80, and 80–100 in a frequency distribution of the data. 2. __________________ 3. Make a histogram of the data. 3. 4. Find the mean of the data. 4. __________________ 5. Find the median of the data. 5. __________________ 6. Find the mode of the data. 6. __________________ 7. Find the value of x so that the mean of {3x 3, x 5, 3x, 2x 7} is 9. 7. __________________ 8. Find the mean of the data below. stem leaf 0 4 7 8 9 9 1 0 1 2 3 3 4 5 6 6 8 9 2 1 2 5 8 0|4 4 8. __________________ For Exercises 9 and 10, use the frequency distribution below. Class Frequency Class Frequency 325–375 8 575625 10 375–425 10 625675 6 425–475 30 675725 2 475–525 20 725775 1 525–575 12 775825 1 9. Estimate the mean of the data. 9. __________________ 10. Estimate the median of the data. 10. __________________ © Glencoe/McGraw-Hill 633 Advanced Mathematical Concepts NAME _____________________________ DATE _______________ PERIOD ________ Chapter 14 Chapter 14 Test, Form 2B (continued) The table below gives the percent pay raise for 13 employees. Use the table for Exercises 11–13. Percent Pay Raise 3.2% 4.4% 4.1% 3.8% 1.5% 2.4% 3.3% 1.7% 9.2% 4.5% 4.2% 5.1% 4.6% 11. Find the mean deviation of the percentages. 11. __________________ 12. Find the standard deviation of the percentages. 12. __________________ 13. Make a box-and-whisker plot of the percentages. 13. For Exercises 14-16, a set of data has a normal distribution with a mean of 120 and a standard deviation of 10. 14. What percent of the data is between 100 and 140? 14. __________________ 15. Find the interval about the mean within which 80% of the data lie. 15. __________________ 16. Find the probability that a value selected at random from this data is between 105 and 135. 16. __________________ In a random sample of 256 people, it was found that each person ate fast food an average of 2.6 times per week with a standard deviation of 0.4. 17. Find the standard error of the mean. 17. __________________ 18. Find the interval about the sample mean that has a 1% level of confidence. 18. __________________ 19. Find the interval about the sample mean such that the probability is 0.80 that the mean number lies within the interval. 19. __________________ 20. Find the probability that the mean of the population will be less than 0.1 from the mean of the sample. 20. __________________ Bonus Find the probability that the true mean is between 2.55 and 2.575. © Glencoe/McGraw-Hill 634 Bonus: __________________ Advanced Mathematical Concepts NAME _____________________________ DATE _______________ PERIOD ________ Chapter 14 Chapter 14 Test, Form 2C The speeds of 50 cars in a 70 mile-per-hour zone are recorded in the chart below. Use the chart for Exercises 1–6. Speed (miles per hour) 66 69 70 67 74 88 71 65 68 73 69 72 67 69 68 68 68 58 69 67 72 65 72 59 63 73 72 65 66 67 58 63 73 66 77 66 62 52 63 81 64 71 72 67 65 73 64 71 65 64 1. List the stems that would be used in a stem-and-leaf plot of the data. 1. __________________ 2. List the class marks for the intervals 50–60, 60–70, 70–80, and 80–90 in a frequency distribution of the data. 2. __________________ 3. Make a histogram of the data. 3. 4. Find the mean of the data. 4. __________________ 5. Find the median of the data. 5. __________________ 6. Find the mode of the data. 6. __________________ 7. Find the value of x so that the mean of {x, 3x, 2x 1, 2x 5} is 15. 7. __________________ 8. Find the mean of the data below. stem leaf 6 4 5 5 5 6 7 8 8 8 8 9 7 0 0 0 1 1 1 2 2 2 2 3 7 8 0 2 6|4 6.4 8. __________________ For Exercises 9 and 10, use the frequency distribution below. Class Frequency Class Frequency 0-10 3 50-60 7 10-20 6 60-70 5 20-30 8 70-80 4 30-40 7 80-90 1 40-50 6 90-100 3 9. Estimate the mean of the data. 9. __________________ 10. Estimate the median of the data. 10. __________________ © Glencoe/McGraw-Hill 635 Advanced Mathematical Concepts NAME _____________________________ DATE _______________ PERIOD ________ Chapter 14 Chapter 14 Test, Form 2C (continued) The table below gives the number of traffic tickets issued per day over a 20-day period by a police officer. Use the table for Exercises 11–13. Number of Traffic Tickets Issued 7 12 10 8 7 12 15 10 10 7 14 6 10 12 9 8 8 2 9 12 11. Find the mean deviation of the data. 11. __________________ 12. Find the standard deviation of the data. 12. __________________ 13. Make a box-and-whisker plot of the data. 13. For Exercises 14–16, a set of data has a normal distribution with a mean of 8 and a standard deviation of 1.4. 14. What percent of the data is between 7 and 9? 14. __________________ 15. Find the interval about the mean within which 90% of the data lie. 15. __________________ 16. Find the probability that a value selected at random from this data is between 7.3 and 8.7. 16. __________________ In a random sample of 100 band students, it was found that each student practiced an average of 10.5 hours per week with a standard deviation of 1.4 hours. 17. Find the standard error of the mean. 17. __________________ 18. Find the interval about the sample mean that has a 5% level of confidence. 18. __________________ 19. Find the interval about the sample mean such that the probability is 0.90 that the mean number lies within the interval. 19. __________________ 20. Find the probability that the mean of the population will be less than 15 minutes from the mean of the sample. 20. __________________ Bonus Find the probability that the true mean is between 10.2 and 10.6 hours. © Glencoe/McGraw-Hill 636 Bonus: __________________ Advanced Mathematical Concepts NAME _____________________________ DATE _______________ PERIOD ________ Chapter 14 Chapter 14 Open-Ended Assessment Instructions: Demonstrate your knowledge by giving a clear, concise solution to each problem. Be sure to include all relevant drawings and justify your answers. You may show your solution in more than one way or investigate beyond the requirements of the problem. 1. The table and graph below show the distribution of grades for an English test. English Scores Class Limits Class Mark Frequency 62.5–67.5 65 1 67.5–72.5 70 2 72.5–77.5 75 3 77.5–82.5 80 5 82.5–87.5 85 7 87.5–92.5 90 9 92.5–97.5 95 7 97.5–102.5 100 3 a. Are the grades on the test normally distributed? Why or why not? b. Which measure of central tendency (mean, median, or mode) will be the greatest? Why? c. Which measure of central tendency will be the least? Why? 2. The combined test scores for all of the advanced mathematics classes in a school are normally distributed. The mean score is 85, and the standard deviation is 10. There are 200 students in the classes. a. Those who had scores above 100 were given a grade of A. How many students received an A? Explain your reasoning. b. What are the mode and median for the set of scores? How do you know? c. Those who had scores between 80 and 90 were given a grade of C. How many students received a C? Explain your reasoning. d. If the teacher changes the range for the grade of C to scores from 75 to 85, will there be an increase or decrease in the number of C grades? Explain your reasoning. 3. Consider the statement “Given two sets of data, the mean of the combination of the two sets equals the mean of the means.” Provide an example that disproves the statement. In what situation is the statement true? © Glencoe/McGraw-Hill 637 Advanced Mathematical Concepts NAME _____________________________ DATE _______________ PERIOD ________ Chapter 14 Chapter 14 Mid-Chapter Test (Lessons 14-1 through 14-3) The amount of money 13 families spent on food in one year is recorded in the table below. Use the table for Exercises 1–7. Food Expenses (thousands of dollars) 4.5 5.2 6.5 2.9 2.7 4.6 3.9 6.0 4.7 4.2 5.2 4.6 7.2 1. Organize the data into a frequency distribution. 1. __________________ 2. List the stems that would be used in a stem-and-leaf plot of the data. 2. __________________ 3. Make a box-and-whisker plot of the data. 3. 4. Find the mean of the data. 4. __________________ 5. Find the mode of the data. 5. __________________ 6. What is the mean deviation for the data? 6. __________________ 7. What is the standard deviation for the data? 7. __________________ The weights of baseball players on the Chicago White Sox 1999 roster are recorded in the table below. Use the table for Exercises 8–10. Weight (in pounds) Frequency 160–180 6 180–200 13 200–220 8 220–240 3 240–260 2 Source: Yahoo! Sports 8. Estimate the mean weight of the players. 8. __________________ 9. Estimate the median weight of the players. 9. __________________ 10. Estimate the standard deviation of the weights. © Glencoe/McGraw-Hill 638 10. __________________ Advanced Mathematical Concepts NAME _____________________________ DATE _______________ PERIOD ________ Chapter 14 Chapter 14, Quiz A (Lessons 14-1 and 14-2) Use the data in the table below for each exercise. 28 16 37 31 21 26 35 29 12 24 28 34 32 26 19 25 35 31 28 26 19 22 30 24 19 29 33 1. Find the range and determine an appropriate class interval. 1. __________________ 2. Find the class marks. 2. __________________ 3. Draw a histogram of the data. 3. 4. Draw a stem-and-leaf plot of the data. 4. 5. Find the mean, median, and mode of the data. 5. __________________ stem leaf NAME _____________________________ DATE _______________ PERIOD ________ Chapter Chapter 14, Quiz B (Lesson 14-3) 14 Use the data in the table below for Exercises 1-14. Heights of Women Basketball Players on the Houston Comets 1999 Roster (inches) 71 70 67 74 77 75 66 72 74 76 73 79 Source: WNBA 1. Find the mean deviation of the heights. 1. __________________ 2. Find the interquartile range for the data. 2. __________________ 3. Find the semi-interquartile range for the data. 3. __________________ 4. What is the standard deviation of the heights? 4. __________________ 5. Make a box-and-whisker plot of the data. 5. © Glencoe/McGraw-Hill 639 Advanced Mathematical Concepts NAME _____________________________ DATE _______________ PERIOD ________ Chapter 14 Chapter 14, Quiz C (Lesson 14-4) A set of 900 values has a normal distribution with a mean of 150 and a standard deviation of 8. 1. What percent of the data is between 134 and 166? 1. __________________ 2. How many values are within one standard deviation of the mean? 2. __________________ 3. How many values fall in the interval between one and two standard deviations of the mean? 3. __________________ 4. Find the probability that a value selected at random from the data will be greater than 162. 4. __________________ 5. Find the interval about the mean that includes 90% of the data. 5. __________________ NAME _____________________________ DATE _______________ PERIOD ________ Chapter 14 Chapter 14, Quiz D (Lesson 14-5) In a sample of 100 adults, the average time each adult kept a car was 6.2 years. The standard deviation was 1.1 years. 1. Find the standard error of the mean. 1. __________________ 2. Find the interval about the sample mean that has a 5% level of confidence. 2. __________________ 3. Find the interval about the sample mean that has a 1% level of confidence. 3. __________________ 4. Find the probability that the mean of the population will be less than 0.1 year from the mean of the sample. 4. __________________ 5. Find the probability that the mean of the population will be less than 0.5 year from the mean of the sample. 5. __________________ © Glencoe/McGraw-Hill 640 Advanced Mathematical Concepts NAME _____________________________ DATE _______________ PERIOD ________ Chapter 14 Chapter 14 SAT and ACT Practice After working each problem, record the correct answer on the answer sheet provided or use your own paper. Multiple Choice 1. Use the graph below to determine how many more items were sold in January than in May. A 5250 B 3500 C 1750 D 4250 E 1000 5. Of the 50 students in a class, exactly 30 are women. What percent of the students are men? A 20% B 30% C 40% D 50% E 60% 6. Five is what percent of 2? A 2.5% B 25% C 40% D 250% E 400% 7. 2. In the graph below, which of the following could be the percent change from the number of widgets built in 1985 to the number built in 1990? Long Distance Rates From City A First Minute Each Additional Minute to City B $0.55 $0.15 to City C $0.25 $0.05 Based on the table above, what is the cost of a 30-minute call from City B to City C? A $4.90 B $5.05 C $7.30 D $7.55 E It cannot be determined from the information given. A B C D E 150% decrease 67% decrease 60% decrease 67% increase 300% increase 8. Attendance Age Number of Students 14 15 16 17 5 6 10 10 Based on the table above, what is the mean age of the students? A 14.6 B 15.0 C 15.8 D 16.5 E 16.8 3. If 5 more than x is 2 less than y, what is y in terms of x? A x3 B y7 C y3 D x7 E x7 9. Point A is on line m. If two points, B and C, are each placed to the right of point A so that AB 2AC, what will AC ? be the value of BC 4. If 5x 3y 23 and x and y are positive integers, then y can equal which of the following? A 3 B 4 C 5 D 6 E 7 A 1 B 2 1 2 D 14 C E It cannot be determined from the information given. © Glencoe/McGraw-Hill 641 Advanced Mathematical Concepts NAME _____________________________ DATE _______________ PERIOD ________ Chapter 14 Chapter 14 SAT and ACT Practice 10. In ABC below, which of the following could be a value of y? A 2 B 4 C 6 D 8 E 12 11. Mosin’s monthly expenses are $1375 per month and are distributed as shown in the pie chart below. How much does he spend for “other” expenses each month? A $206.25 B $137.50 C $68.75 D $13.75 E $10 17–18. Quantitative Comparison A if the quantity in Column A is greater B if the quantity in Column B is greater C if the two quantities are equal D if the relationship cannot be determined from the information given Column A 17. Mean of 101, 202, and 303 Column B Mean of 101, 202, 303, and 10 18. Set X {1, 2, 2, 3, 3, 3, 4, 4, 4, 4} 13. Which of the following ratios is equal to the ratio of 14 to 4? B 4 to 14 A 13 to 3 Mode of Set X C 18 to 2 D 12 to 2 E None of these 14. A car traveling 60 miles per hour for 30 minutes covers the same distance as a car traveling 20 miles per hour for how many hours? B 1 A 23 © Glencoe/McGraw-Hill 15. Use the chart below to determine the number of boxes of cabbage sold by a farmer in 1998. A 1000 B 4000 C 8000 D 10,000 E 40,000 16. Use the chart above to determine how many more boxes of cabbage were sold in 1999 than in 2000. A 250 B 500 C 5000 D 1000 E 2500 12. If Mosin’s monthly expenses are $1225 per month and are distributed as shown in the pie chart above, how much more does he spend on rent than on food? A $68.75 B $72.50 C $7.25 D $61.25 E $612.50 C 112 E 13 (continued) D 3 Median of Set X 19–20. In a class of 250 students, 4 are running for the position of class president. Every student in the class voted exactly once. The votes were distributed as shown below. Candidate Number of Votes D.J. 75 Belinda 20 Darius 45 Lou Ann x 19. Grid-In How many votes did Lou Ann get? 20. Grid-In What was the median number of votes per candidate? 642 Advanced Mathematical Concepts NAME _____________________________ DATE _______________ PERIOD ________ Chapter 14 Chapter 14, Cumulative Review (Chapters 1-14) 1. Write the ordered triple that represents CD for C(5, 0, 1) and D(3, 2, 6). 1. __________________ 2. Write an equation of the cosine function with amplitude 6, phase shift 0, vertical shift 0, and period 12. 2. __________________ 3. Write the polynomial equation of least degree with roots 7i and 7i. 3. __________________ 4. Find the area of A BC to the nearest tenth if c 11.4, B 31.6 and C 120.3. 4. __________________ 3 5. Find 8i. 5. __________________ 6. Write in general form the equation of a parabola whose focus is at (5, 1) and whose directrix is x 3. 6. __________________ 1 3 in exponential form. 7. Write log5 125 7. __________________ 8. Find the first three iterates of the function ƒ(z) z2 z i if z0 i. 8. __________________ 9. The serial number for a product is formed from the digits 1, 2, and 3 and the letters A and B. No letters or numbers are repeated. What is the probability that the serial number ends in 2A given that it ends in a letter? 9. __________________ 10. A set of data has a normal distribution with a mean of 16 and a standard deviation of 0.3. What percent of the data is in the interval 15.216? 10. __________________ © Glencoe/McGraw-Hill 643 Advanced Mathematical Concepts Blank NAME _____________________________ DATE _______________ PERIOD ________ UNIT 4 Unit 4 Review, Chapters 12-14 Solve. 1. Find the 20th term in the arithmetic sequence for which a1 3 and d 2. 2. Find the sum of the first nine terms of the geometric series 2 4 8 . . . . 3. Write an arithmetic sequence that has two arithmetic means between 3 and 9. 24. ƒ(x) 1x, x0 2 Find the first three iterates of the function ƒ(z) 2z 3i for each initial value. 26. z0 3 i 25. z0 i Find each limit or state that the limit does not exist. n 1 6. lim n 7. lim 42n 8. lim n2 2 (4n 5)(n 3) Find the sum of each series or state that the sum does not exist. 9. 1 1 1 . . . 10. 2 4 1 1 4 11 6 ... Determine whether each series is convergent or divergent. 11. 1 4 7 10 . . . 12. 13. Write each expression in expanded form and then find the sum. 14. 2k 15. (3a 6) a2 17. k1 8 16. Use mathematical induction to prove that each proposition is valid for all positive integral values of n. 27. 3 9 15 . . . (6n 3) 3n2 28. 5 n 1 is divisible by 4 Find each value. 29. P(9, 6) 30. P(7, 4) 31. C(8, 2) 32. C(6, 5) Solve. 33. The letters a, b, c, d, and e are to be used to form 5-letter patterns. How many patterns can be formed if repetitions are not allowed? 6 2 23 29 . . . 31 32 33 . . . 1 2 3 5 Find the first three iterates of each function using the given initial value. If necessary, round your answers to the nearest hundredth. 22. ƒ(x) 3x 1, x0 1 23. ƒ(x) x2 5, x0 2 4. Find the sixth term of the geometric sequence 13, 145, 1765, . . . . 4n 1 5. lim 3n Use the first five terms of the exponential series and a calculator to approximate each value to the nearest hundredth. 21. e0.3 20. e1.72 7 34. How many different 5-member teams can be formed from 10 players? k1 6 35. How many different ways can the letters of the word color be arranged? (2k2 1) 312k k0 36. From a group of 3 men and 5 women, how many different committees of 2 men and 2 women can be formed? Find the designated term of each binomial expansion. 37. How many different ways can 8 keys be arranged on a circular key ring? 18. 4th term of (3x 1)9 19. 7th term of (x 2y)12 © Glencoe/McGraw-Hill 645 Advanced Mathematical Concepts NAME _____________________________ DATE _______________ PERIOD ________ UNIT 4 Unit 4 Review, Chapters 12-14 (continued) State the odds of an event occurring, given the probability of the event. 1 39. 38. 27 14 40. 121 56. A population is normally distributed with a mean of 60 and a standard deviation of 5. What is the probability that a randomly selected value will be greater than 65? 57. A set of data is normally distributed with a mean of 70 and a standard deviation of 6. What is the probability that a randomly selected value lies between 65 and 75? 3 41. 13 Solve. 42. Three cards are drawn at random from a standard deck of 52 cards. What is the probability that all three are clubs? 43. Find the probability of getting a sum of 6 on the first throw of two number cubes and a sum of 2 on the second throw. 44. Find the probability of getting a sum of 7 or 9 on a single throw of two number cubes. 45. One card is drawn from a standard deck of 52 cards. What is the probability that it is a king if it is known to be a face card? Solve. 58. Find the interval about the mean within which 77% of the values of a set of normally distributed data can 67 and 3.2. be found if X 59. Find the interval about the mean within which 16% of the values of a set of normally distributed data can 0.25 and 0.12. be found if X Renee is a forward on her school’s soccer team. The probability of her making a goal is 14. Find each probability if Renee makes 5 attempts on the goal. 46. P(3 goals) 47. P(at least 2 goals) The test scores for Ms. Humphrey’s humanities class are listed below. 89 95 77 99 65 65 70 89 77 72 82 80 66 42 69 76 91 86 82 77 48. 49. 50. 51. 52. 53. Find the standard error of the mean for each sample. 60. 8, N 100 61. 3.23, N 30 62. 5, N 38 63. 12.3, N 89 Solve. 64. A set of data of size N 100 is normally distributed with a mean of 50 and a standard deviation of 5. Determine the interval about the sample mean that has a 1% level of confidence. Find the range of the data. Find the mean of the data. Find the median of the data. Find the mode of the data. Find the mean deviation of the data. Find the semi-interquartile range of the data. 54. Find the standard deviation of the data. 65. A set of data of size N 30 is normally distributed with a mean of 100 and a standard deviation of 3.3. Determine the interval about the sample mean that has a 1% level of confidence. Solve. 55. A set of data is normally distributed with a mean of 30 and a standard deviation of 7. What percent of the data is between 9 and 51? 66. A set of data of size N 36 is normally distributed with a mean of 20 and a standard deviation of 4.2. Determine the interval about the sample mean that has 5% level of confidence. © Glencoe/McGraw-Hill 646 Advanced Mathematical Concepts NAME _____________________________ DATE _______________ PERIOD ________ UNIT 4 Unit 4 Test, Chapters 12-14 1. Express 23 29 35 41 47 using sigma notation. 1. __________________ 2. A set of data is normally distributed with a mean of 16 and a standard deviation of 0.3. What percent of the data is between 15.2 and 16? 2. __________________ 3. Use mathematical induction to prove that n(n 1)(2n 1) for 12 22 32 . . . n2 6 all positive integral values of n. 3. __________________ , 1, 1, . . . . 4. Find the twelfth term of the geometric sequence 11 6 8 4 4. __________________ 5. There are 21 wrapped packages in a grab bag at an office holiday party. Five of the packages contain $20 bills, 7 packages contain $5 bills, and 9 packages contain $1 bills. What is the probability that the first two people will choose packages with $20 bills inside? 5. __________________ .... 6. Find the sum of the infinite series 1 15 21 5 6. __________________ 7. Find P(5, 2). 7. __________________ 8. True or false: Choosing an entrée and choosing an appetizer from a dinner menu are independent events. 8. __________________ 9. How many ways can 9 keys be arranged on a circular key ring? 9. __________________ 10. Determine whether the series 1 215 315 415 . . . is convergent or divergent. 10. __________________ 11. What is the probability of getting an even number on a single roll of a number cube if you roll a 3 or greater? 11. __________________ 12. How many eight-letter patterns can be formed from the letters of the word circular? 12. __________________ © Glencoe/McGraw-Hill 647 Advanced Mathematical Concepts NAME _____________________________ DATE _______________ PERIOD ________ UNIT 4 Unit 4 Test, Chapters 12-14 (continued) 13. Use the ratio test to determine whether the series 1 12 13 . . . is convergent or divergent. 3 3 3 13. __________________ 14. Find the first three iterates of the function ƒ(z) z2 z i, if the initial value is i. 14. __________________ 15. The probability of being named captain of the basketball team is 15. What are the odds of being named captain of the team? 15. __________________ 16. Eight out of ten people surveyed prefer to observe Veterans 16. __________________ Day on November 11 rather than on the second Monday of November. Use the Binomial Theorem to determine the probability that each of the first three people surveyed prefer to observe Veterans Day on November 11. 17. Use the Binomial Theorem to expand (x 2y) 3. 17. __________________ 18. Find the probability of tossing 2 heads on 3 tosses of a fair coin. 18. __________________ 19. Find n for the arithmetic sequence for which an 129, a1 15, and d 6. 19. __________________ 20. The set of class marks in a frequency distribution is {25.5, 35.5, 45.5, 55.5}. Find the class interval and the class limits. 20. __________________ 21. Use the first five terms of the exponential series and a calculator to approximate the value of e0.67 to the nearest hundredth. 21. __________________ 22. Find the first three iterates of the function ƒ(x) x2 2, if the initial value is 2. 22. __________________ n2 1 , or state that the limit does not exist. 23. Find lim n 23. __________________ n→ © Glencoe/McGraw-Hill 648 Advanced Mathematical Concepts NAME _____________________________ DATE _______________ PERIOD ________ UNIT 4 Unit 4 Test, Chapters 12-14 (continued) 24. Twenty slips of paper are numbered 1 to 20 and placed 24. __________________ in a box. What is the probability of drawing a number that is odd or a multiple of 5? 25. Find C(10, 4). 25. __________________ The table below shows the number of gallons of heating oil delivered to a residential customer each December from 1986 to 1993. Use the table for Exercises 26-28. Year Gallons of Oil 1986 1987 1988 1989 1990 1991 1992 1993 42 61 53 59 53 51 75 100 26. Make a stem-and-leaf plot of the data. 26. __________________ 27. Find the mean, median, and mode of the data. 27. __________________ 28. Find the interquartile range and the semi-interquartile range of the data. 28. __________________ 29. Two cards are drawn at random from a standard deck of 52 cards. What is the probability that both cards are queens? 29. __________________ 6 as a fraction. 30. Write 0.3 30. __________________ 31. Find the 50th term in the arithmetic sequence 1, 5, 9, . . . . 31. __________________ 32. A set of data is normally distributed with a mean of 50 points and a standard deviation of 10 points. What percent of the data is greater than 60? 32. __________________ © Glencoe/McGraw-Hill 649 Advanced Mathematical Concepts NAME _____________________________ DATE _______________ PERIOD ________ UNIT 4 Unit 4 Test, Chapters 12-14 (continued) 33. A red number cube and a white number cube are rolled. Find the probability that the red number cube shows a 2, given that the sum showing on the two number cubes is less than or equal to 5. 33. __________________ 34. Find the standard error of the mean for a sample in which 34. __________________ 3.6, N 100, and X 36. Then use t 2.58 to find the interval about the sample mean that has a 1% level of confidence. Round your answer to the nearest hundredth. The table below shows a frequency distribution of the number of pickup trucks sold at 85 truck dealerships in Maine over an 18-month period. Number of Trucks Sold 7090 90110 110130 130150 150170 170190 Number of Dealerships 2 11 39 17 9 7 35. Find the interval about the sample mean such that the probability is 0.90 that the true mean lies within the interval. (When P 90%, t 1.65.) 35. __________________ A set of data is normally distributed with a mean of 500 and a standard deviation of 40. 36. What percent of the data is between 460 and 540? 36. __________________ 37. Find the probability that a value selected at random is less than 420. 37. __________________ Suppose that the respondents in a survey of 100 teenagers watch an average of 10 hours of television per week. The standard deviation of the sample is 2.5 hours. 38. Find the standard error of the mean. 38. __________________ 39. What is the interval about the sample mean that has a 1% level of confidence? 39. __________________ 40. Find the interval about the sample mean that gives a 90% chance that the true mean lies within the interval. 40. __________________ © Glencoe/McGraw-Hill 650 Advanced Mathematical Concepts NAME _____________________________ DATE _______________ PERIOD ________ SAT and ACT Practice Answer Sheet (10 Questions) . / . / . . 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 © Glencoe/McGraw-Hill A1 Advanced Mathematical Concepts NAME _____________________________ DATE _______________ PERIOD ________ SAT and ACT Practice Answer Sheet (20 Questions) . / . / . . 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 . / . / . . 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 © Glencoe/McGraw-Hill A2 Advanced Mathematical Concepts © Glencoe/McGraw-Hill 6.2 A3 9.5 Phoenix New Orleans Memphis Las Vegas Honolulu Boston Anchorage Station 6.2 8.1 8.8 9.3 11.3 12.5 7.1 Seattle New York City Miami Little Rock Indianapolis Chicago Atlanta Station 9.0 9.4 9.2 7.8 9.6 10.4 9.1 Speed (mph) © Glencoe/McGraw-Hill Wind Speed (mph) 6.0–7.0 7.0–8.0 8.0–9.0 9.0–10.0 10.0–11.0 11.0–12.0 12.0–13.0 610 Tallies Frequency 兩兩 2 兩兩 2 兩兩兩 3 兩兩兩兩 兩兩兩 8 兩兩兩兩 4 兩 1 兩 1 e. Draw a histogram of the data. d. Construct a frequency distribution of the data. e. Advanced Mathematical Concepts Sample answer: 6.0, 7.0, 8.0, 9.0, 10.0, 11.0, 12.0, 13.0; 6.5, 7.5, 8.5, 9.5, 10.5, 11.5, 12.5 c. What are the class limits and the class marks? Sample answer: 1 Speed (mph) b. Determine an appropriate class interval. a. Find the range of the data. 6.3 Source: National Climatic Data Center Philadelphia 10.5 Los Angeles Minneapolis– St. Paul 10.8 10.7 Kansas City 9.1 Dallas-Ft. Worth 8.9 Baltimore Speed (mph) Albuquerque Station 3. Meteorology The average wind speeds recorded at various weather stations in the United States are listed below. 1. 25, 32, 18, 99, 43, 16, 29, 35, 36, 34, 2. 111, 115, 130, 200, 234, 98, 115, 72 21, 33, 26, 26, 17, 40, 22, 38, 16, 19 305, 145, 87, 63, 245, 285, 256, 302 a. 25 yes; 10 classes a. 1 no; too many classes b. 10 yes; 8 classes b. 10 no; too many classes c. 2 no; too many classes c. 30 yes; 9 classes © Glencoe/McGraw-Hill 611 Advanced Mathematical Concepts 3. If 10,000 cars were sold, how many are still on the road? 9,000 4. If 1000 cars were sold, how many are still on the road? 900 5. Find an example to show how you think averages could be used in a misleading way. See students’ work. 6. A survey of a large sample of people who own small computers revealed that 85% of the people thought the instruction manuals should be better written. A manufacturer of small computers claimed that it surveyed many of the same people and found that all of them liked their manuals. Discuss the possible discrepancy in the results. See students’ work. 2. Suppose that a car company claims, “75% of people surveyed say that our car is better than the competition.” If only four people were surveyed, how many people thought that this company’s car was better? 3 people Suppose an advertiser claims that 90% of all the cars of one brand sold in the last 10 years are still on the road. the first graph 1. Which graph would you use to give the impression that the unemployment rate dropped dramatically from 1982 to 1990? Notice that the two graphs show the same data, but the spacing in the vertical and horizontal scales differs. Scales can be cramped or spread out to make a graph that gives a certain impression. Statistics can be misleading. Two graphs for the same set of data can look very different from each other. Compare the following graphs. Enrichment Misuses of Statistics 14-1 Determine which class intervals would be appropriate for the data below. Explain your answers. Practice NAME _____________________________ DATE _______________ PERIOD ________ The Frequency Distribution 14-1 NAME _____________________________ DATE _______________ PERIOD ________ Answers (Lesson 14-1) Advanced Mathematical Concepts © Glencoe/McGraw-Hill 23; 19; 22 and 19 4. {18, 6, 22, 33, 19, 34, 14, 54, 12, 22, 19} 55.9; 56.5; 94 2. {32, 12, 61, 94, 73, 62, 94, 35, 44, 52} A4 about 357.3; 330; 240 Stem Leaf 2 2 4 4 7 3 1 3 4 4 5 6 8 5 9 2/2 ⫽ 220 7. about 103.42; 104; 91 Stem Leaf 9 0113 10 1 3 5 6 11 3 4 6 8 9/0 ⫽ 90 © Glencoe/McGraw-Hill 613 9. Medicine A frequency distribution for the number of patients treated at 50 U.S. cancer centers in one year is given at the right. a. Use the frequency chart to find the mean of the number of patients treated by a cancer center. 1210 b. What is the median class of the frequency distribution? 500–1000 6. 6 0 2 0 2 1000–1500 1500–2000 2000–2500 2500–3000 3000–3500 3500–4000 Advanced Mathematical Concepts Source: U.S. News Online 26 14 500–1000 Patients about 3.59; 3.2; 2.3 Stem Leaf 1 1 2 9 2 3 3 5 3 2 4 0 5 4 5 6 8 9 1/1 ⫽ 1.1 Number of Cancer Centers 8. Find the mean, median, and mode of the data represented by each stem-and-leaf plot. 5. A shoe store employee sets up a display by placing shoeboxes in 10 stacks. The numbers of boxes in each stack are 5, 7, 9, 11, 13, 10, 9, 8, 7, and 5. a. What is the mean of the number of boxes in a stack? 8.4 b. Find the median of the number of boxes in a stack. 8.5 c. If one box is removed from each stack, how will the mean and median be affected? Each will decrease by 1 box. 246; 152; no mode 3. {152, 697, 202, 312, 109, 134, 116} 42.83; 40.5; 42 1. {15, 42, 26, 39, 93, 42} 30 ⫹ 55 ᎏ 2 or 42.5 mph. 100 ᎏ 50 ⫹ 100 ᎏ, 55 or about 52.4 mph. We apply the formula to Bill’s speeds. Let n ⫽ number of rates xi where 1 ⱕ i ⱕ n. i⫽1 冱 n ᎏᎏᎏ n 1 __ xi or H ⬇ 52.4 mph 2 H ⫽ ______ 1 1 ᎏ ⫹ ᎏ 50 55 H ⫽ Bill’s average speed also may be found by using the formula for the harmonic mean as follows. 200 ᎏ, 3.82 approximately 3.82 hours. His average speed was varied. Actually, the time he drove was On the other hand, Bill drove the same distance on both portions of his driving, but the two lengths of time two rates. Her average speed was Kendra drove the same length of time on both portions of her driving, so her average speed is the mean of the Recently Kendra and Bill took a trip of 370 miles and shared the driving. Kendra drove two hours at a rate of 30 mph and then drove the next 110 miles on a freeway at 55 mph. Then Bill drove the next two hours at 50 mph and he drove the last 100 miles on a freeway at 55 mph. What was the average speed of each driver? 10.95 2. {5, 10, 15, 20, 25} © Glencoe/McGraw-Hill 614 Advanced Mathematical Concepts 3. Bev, Phyllis, and Gordon competed in a 375-mile relay race. Bev drove 40 mph, Phyllis drove 50 mph, and Gordon drove 60 mph. If each drove 125 miles, find the average driving speed of the contestants. 48.65 mph 4.21 1. {3, 4, 5, 6} Find the harmonic mean of each set of data. Round each answer to the nearest hundreth. The mean, also called the arithmetic mean, is used when equal times are involved. When equal distances are involved, the harmonic mean is used. Example The harmonic mean H is a useful measure of central tendency in special cases of averaging rates. Enrichment The Harmonic Mean 14-2 Find the mean, median, and mode of each set of data. Practice NAME _____________________________ DATE _______________ PERIOD ________ Measures of Central Tendency 14-2 NAME _____________________________ DATE _______________ PERIOD ________ Answers (Lesson 14-2) Advanced Mathematical Concepts © Glencoe/McGraw-Hill A5 4.7, 2.35 © Glencoe/McGraw-Hill about 1.16 d. What is the standard deviation of the male life expectancy? about 1.02 c. What is the standard deviation of the female life expectancy? b. Find the mean of the male life expectancy. 73.85 616 5. Sociology The frequency distribution at the right shows the average life expectancy for males and females in 15 European Union countries in 1994. a. Find the mean of the female life expectancy. 79.85 334.84, 433.25 4 8 3 0 0 0 0 Female Advanced Mathematical Concepts Source: Department of Health and Children, Ireland 0 80.5⫺82.0 1 76.0⫺77.5 0 2 74.5⫺76.0 79.0⫺80.5 9 73.0⫺74.5 0 3 71.5⫺73.0 77.5⫺79.0 Male Life Expectancy (years) Frequency 4. 1592, 1486, 1479, 1682, 1720, 1104, 1486, 1895, 1890, 2687, 2450 37.1, 51.99 Find the mean deviation and the standard deviation of each set of data. 3. 146, 289, 121, 146, 212, 98, 86, 153, 128, 136, 181, 142 2. 1.6, 9.8, 4.5, 6.2, 8.7, 5.6, 3.9, 6.8, 9.7, 1.1, 4.7, 3.8, 7.5, 2.8, 0.1 44, 22 Notice that no one had a score of 56 points. Thus, the score at the 16th percentile is 56. What score is at the 16th percentile? A score at the 16th percentile means the score just above the lowest 16% of the scores. 16% of the 50 scores is 8 scores. The 8th score is 55. The score just above this is 56. 3 1 50 45 28th 11. a score of 62 ______ 1 4 8 14 21 29 36 42 47 49 50 Cumulative Frequency Advanced Mathematical Concepts 84th 12. a score of 81 ______ 90th 9. a score of 85 ______ © Glencoe/McGraw-Hill 72nd 8. a score of 77 ______ 16th 10. a score of 58 ______ 6th 7. a score of 50 ______ 617 Use the table above to find the percentile of each score. 33 out of 50 is 66%. Thus, a score of 75 is at the 66th percentile. Adding 4 scores to the 29 gives 33 scores. At what percentile is a score of 75? There are 29 scores below 75. Seven scores are at 75. The fourth of these seven is the midpoint of this group. 81 6. 80th percentile ______ Example 2 86 4. 90th percentile ______ 71 5. 58th percentile ______ 76 2. 70th percentile ______ 4 55 6 7 65 60 8 70 6 80 7 5 85 75 2 1 95 90 Frequency Score 66 3. 33rd percentile ______ 66 1. 42nd percentile ______ Use the table above to find the score at each percentile. Example 1 The table at the right shows test scores and their frequencies. The frequency is the number of people who had a particular score. The cumulative frequency is the total frequency up to that point, starting at the lowest score and adding up. Enrichment Percentiles 14-3 Find the interquartile range and the semi-interquartile range of each set of data. Then draw a box-and-whisker plot. 1. 43, 26, 92, 11, 8, 49, 52, 126, 86, 42, 63, 78, 91, 79, 86 Practice NAME _____________________________ DATE _______________ PERIOD ________ Measures of Variability 14-3 NAME _____________________________ DATE _______________ PERIOD ________ Answers (Lesson 14-3) Advanced Mathematical Concepts © Glencoe/McGraw-Hill A6 © Glencoe/McGraw-Hill 1.05% 619 Advanced Mathematical Concepts b. What percent of the full-grown German shepherds at City View Kennels weigh less than Skipper? 98.95% a. What percent of the full-grown German shepherds at City View Kennels weigh more than Skipper? 7. Dog Breeding The weights of full-grown German shepherds at the City View Kennels are normally distributed. The mean weight is 86 pounds, and the standard deviation is 3 pounds. Skipper, a full-grown German shepard, weighs 79 pounds. 6. Find the limit below which 90% of the data lie. 146 96–144 5. Find the interval about the mean that includes 77% of the data. 87–153 4. Find the interval about the mean that includes 90% of the data. 3. What percent of the data is between 90 and 110? 24.15% 2. What percent of the data is between 110 and 130? 38.3% 683 1. How many values are within one standard deviation of the mean? symmetric symmetric 5. 2. symmetric skewed to the left 6. 3. skewed to the right skewed to the right © Glencoe/McGraw-Hill in the middle of the range; It is the same as the mean. 7. Where is the median in a symmetric distribution? 620 Advanced Mathematical Concepts to the left of the mean if skewed to the right; to the right of the mean if skewed to the left. 8. Where is the median in a skewed distribution? A vertical line along the median divides the area under a frequency curve in half. 4. 1. For each of the following, state whether the distribution is symmetric or skewed. If it is skewed, tell whether it is skewed to the right or to the left. In a distribution skewed to the left, there are a larger number of low values. The long “tail” extends to the left. In a distribution skewed to the right, there are a larger number of high values. The long “tail” extends to the right. Graphs of frequency distributions can be described as either symmetric or skewed. Enrichment Shapes of Distribution Curves 14-4 A set of 1000 values has a normal distribution. The mean of the data is 120, and the standard deviation is 20. Practice NAME _____________________________ DATE _______________ PERIOD ________ The Normal Distribution 14-4 NAME _____________________________ DATE _______________ PERIOD ________ Answers (Lesson 14-4) Advanced Mathematical Concepts © Glencoe/McGraw-Hill 0.22; 109.43–110.57; 109.57–110.43 A7 4 2 Frequency 5 7 1 8 8 9 5 10 1.64 © Glencoe/McGraw-Hill 7.11376–8.80624 min 622 10. Determine the interval about the sample mean that has a 1% level of confidence. 7.31712–8.60288 min Advanced Mathematical Concepts 9. Find the interval about the sample mean such that the probability is 0.95 that the true mean lies within the interval. 7.4188–8.5012 min 8. Find the interval about the sample mean such that the probability is 0.90 that the true mean lies within the interval. 7. Find the standard error of the mean. 0.328 6. Find the standard deviation of the data. 5. What is the mean of the data in the frequency distribution? 7.96 6 5 Number of Minutes The table below shows a frequency distribution of the time in minutes required for students to wash a car during a car wash fundraiser. The distribution is a random sample of 250 cars. Use the table for Exercises 5-10. 4. ⫽ 4.3, N ⫽ 375, 苶 X ⫽ 110 0.16; 49.59–50.41; 49.69–50.31 0.5; 98.71–101.29; 99.02–100.98 2. ⫽ 4, N ⫽ 64, 苶 X ⫽ 100 3. ⫽ 2.6, N ⫽ 250, X 苶 ⫽ 50 5; 237.1–262.9; 240.2–259.8 1. ⫽ 50, N ⫽ 100, 苶 X ⫽ 250 © Glencoe/McGraw-Hill 623 A ⫽ 4, B ⫽ 16, C ⫽ 24, D ⫽ 16, F ⫽ 4 Advanced Mathematical Concepts 1. Draw a smooth curve connecting the tops of the segments whose lengths are proportional to the coefficients in the expansion of (x ⫹ y)12. 2. A teacher decided to mark 64 tests with the grades A, B, C, D, and F (A highest) in proportion to the coefficients in the expansion of (x ⫹ y)4. How many tests received each grade? Solve. The figure above at the right has equally-spaced vertical segments whose lengths are proportional to the numbers in the eighth row of Pascal’s triangle. A smooth curve connecting the tops of these segments suggests the probable distribution of marbles in the column. Notice the similarity of this curve to the normal distribution curve. The numbers in Pascal’s triangle are the coefficients in the expansion of (x ⫹ y)n where n is any positive integer. Therefore, the probability of a marble falling in any given column is proportional to the coefficient of the corresponding term in the binomial expansion of a power. The power is a whole number equal to the row being considered. For example, in the illustration above the columns are in the eighth row. Thus the probability of a marble falling in the third column is proportional to the coefficient of the third term in the binomial expansion of (x ⫹ y)8. It can be shown that the number of paths from A to G is 1, A to J is 1, A to H is 3, and A to I is 3. For example, H can be reached by the way of E. Hence the number of paths to H is the sum of the number of paths to D and the number of paths to E. Likewise the number of paths to any point can be found by adding the number of paths to points diagonally above it. This is precisely the method by which the numbers in Pascal’s triangle are obtained. The picture at the right shows a device often used to illustrate a normal probability distribution. The device is filled with small steel marbles. The marbles roll past a series of hexagonal obstacles, collecting at the bottom in each of nine columns. Enrichment Binomial Expansion Coefficients 14-5 Find the standard error of the mean for each sample. Then find the interval about the sample mean that has a 1% level of confidence and the interval about the sample mean that has a 5% level of confidence. Practice NAME _____________________________ DATE _______________ PERIOD ________ Sample Sets of Data 14-5 NAME _____________________________ DATE _______________ PERIOD ________ Answers (Lesson 14-5) Advanced Mathematical Concepts Chapter 14 Answer Key Form 1A Page 625 1. 2. D Form 1B Page 626 11. C 12. A 3. A 4. D 6. 7. 8. 9. 2. B B 3. D 4. A 5. C B 15. A 6. D 16. C 7. B 8. C B Page 628 11. C 12. A 13. B 14. C 15. D 16. A B 14. A D A 17. B 17. D 18. D 18. B 19. D 19. D 20. B 9. A 10. B B 20. 10. 1. C 13. 5. Page 627 B D Bonus: © Glencoe/McGraw-Hill Bonus: B A8 A Advanced Mathematical Concepts Chapter 14 Answer Key Form 1C Page 629 1. 2. C Page 631 11. D 1. 1, 2, 3, 4, 6, 7, 8 12. C 2. B 3. A 4. B 5. Form 2A Page 630 C 6. D 7. A 8. B 3. 13. C 14. C 15. 16. B Page 632 11. 0.0097 12. 0.0114 67 Sample answer: 13. 4. 31.78 5. 21 14. 6. 18 15. 376–424 7. 5 ᎏ311ᎏ 5 38.3% 16. 95.55% D 8. 5236.875 17. 0.0533 17. B 18. D 19. C 18. 5.06–5.34 19. 5.14–5.26 20. 9. A 10. B 20. Bonus: © Glencoe/McGraw-Hill A 9. 685 10. 697 94.3% Bonus: 2.8% B A9 Advanced Mathematical Concepts Chapter 14 Answer Key Page 633 Form 2B 1. 1, 2, 3, 5, 8 2. 10, 30, 50, 70, 90 Page 634 11. 1.25% 12. 1.85% Form 2C Page 635 1. 5, 6, 7, 8 2. 55, 65, 75, 85 3. Sample answer: Page 636 11. 2.3 12. 2.9 Sample answer: 13. 42.42 5. 44 6. 53 and 57 7. 15 4. 8. 14. 95.5% 15. 107-133 16. 13. 3. 86.6% 14. 4. 67.94 5. 67.5 6. 65, 67, 72 7. 8 8. 7.024 51.6% 15. 5.69–10.31 16. 38.3% 17. 0.14 14.5 17. 9. 497.5 10. 480 0.025 18. 2.5355–2.6645 18. 10.23 –10.77 19. 2.5675–2.6325 19. 10.27–10.73 20. 99.99% 20. Bonus: 13.6% © Glencoe/McGraw-Hill A10 9. 44 10. 41.67 92.9% Bonus: 74% Advanced Mathematical Concepts Chapter 14 Answer Key CHAPTER 14 SCORING RUBRIC Level Specific Criteria 3 Superior • Shows thorough understanding of the concepts histogram, normal distribution, mean, median, mode, central tendency, and standard deviation. • Uses appropriate strategies to solve problems. • Computations are correct. • Written explanations are exemplary. • Goes beyond requirements of problems. 2 Satisfactory, with Minor Flaws • Shows understanding of the concepts histogram, normal distribution, mean, median, mode, central, tendency, and standard deviation. • Uses appropriate strategies to solve problems. • Computations are mostly correct. • Written explanations are effective. • Satisfies all requirements of problems. 1 Nearly Satisfactory, with Serious Flaws • Shows understanding of most of the concepts histogram, normal distribution, mean, median, mode, central tendency, and standard deviation. • May not use appropriate strategies to solve problems. • Computations are mostly correct. • Written explanations are satisfactory. • Satisfies most requirements of problems. 0 Unsatisfactory • Shows little or no understanding of the concepts histogram, normal distribution, mean, median, mode, central tendency, and standard deviation. • May not use appropriate strategies to solve problems. • Computations are incorrect. • Written explanations are not satisfactory. • Does not satisfy requirements of problems. © Glencoe/McGraw-Hill A11 Advanced Mathematical Concepts Chapter 14 Answer Key Open-Ended Assessment Page 637 1a. No; it is not a symmetric bell curve. 1b. Mode; it is not affected by extreme scores. 1c. Mean; it is most affected by extreme scores. 100ᎏ -85 1.5 standard deviations 2a. ᎏ 10 Of the scores, 0.866 lie within 1.5 standard deviation of the mean. 1.00-0.866 ᎏ, or 0.067, lie 1.5 Thus, ᎏ 2 standard deviations above the mean. 0.067 200 13.4, so about 13 students received an A. 2b. They are both 85 because for a normally distributed set of data the mean, median, and mode are equal. 2c. Of the grades, 0.383 are within 0.5 standard deviation of the mean. 0.383 200 76.6, so about 77 students received a C. 2d. A decrease; there are not as many scores in the 75 to 80 range as there are in the 85 to 90 range. © Glencoe/McGraw-Hill A12 3. Counterexample: Let the data sets be {1} and {100, 100, 100, 100}. The mean of the first data set is 1, and the mean of the second data set is 100, so the 1 ᎏ 100 50.5. mean of the means is ᎏ 2 The combination of the two data sets is {1, 100, 100, 100, 100}, which has a mean of 80.2. Thus, the statement is not true in this case. The statement is true, however, if the two data sets 苶 be the have the same size, n. Let Z mean of the combination of two data sets of the same size, and let Xi and Yi be the values in the two sets. Then 苶 Z X1 X2 . . . Xn Y1 Y2 . . .Yn ᎏᎏᎏᎏᎏ 2n X X ...X Y Y ...Y 1 2 n 1 2 n ᎏ12ᎏ 冢 ᎏᎏᎏᎏᎏ 冣 n X X ...X Y Y ...Y 1 2 n 1 2 n ᎏ12ᎏ 冢ᎏᎏᎏ ᎏᎏᎏ 冣 n n 苶 ᎏ X 苶 Y ᎏ12ᎏ ( X 苶苶 Y) ᎏ 2 So, when the data sets are the same size, the mean of the combination data set equals the mean of the means. Advanced Mathematical Concepts Chapter 14 Answer Key Mid-Chapter Test Page 638 1. 2. Sample answer: Costs Frequency 2–4 3 4–6 7 6–8 3 1. 25; Sample answer: 5 1. 95.5% 2. 615 3. 245 4. 6.7% 5. 136.8-163.2 Sample answer: 12.5, 2. 17.5, 22.5, 27.5, 32.5, 37.5 Sample answer: 2, 3, 4, 5, 6, 7 3. 3. 4. Quiz C Page 640 Quiz A Page 639 4. 4.78 stem leaf 1 26999 2 1244566688899 3 011234557 1|2 ⫽ 12 5. 26.6; 28; 19, 26, and 28 5. 4.6 and 5.2 6. 0.95 7. 1.23 Quiz D Page 640 Quiz B Page 639 8. 198.75 lb 9. 195.4 lb 1. about 3.03 1. 0.11 2. 5 in. 2. 5.984-6.416 3. 2.5 in. 3. 5.916-6.484 4. 63.2% 5. 100% 4. about 3.72 5. 10. 21.8 © Glencoe/McGraw-Hill A13 Advanced Mathematical Concepts Chapter 14 Answer Key SAT/ACT Practice Page 641 1. 2. C B Cumulative Review Page 643 Page 642 10. 11. 1. D 2. y 6 cos ᎏ6ᎏt B 3. E 12. D 4. D 13. C 5. C 14. C 具2, 2, 7典 3. x2 49 0 4. 18.6 units2 5. 2i 6. y2 2y 4x 17 0 6. D 15. D 7. 7. E 16. 1ᎏ 53 ᎏ 125 E 8. 1, i, 1 2i 8. C 17. A 9. 9. A © Glencoe/McGraw-Hill 18. A 19. 110 20. 60 10. A14 ᎏ1ᎏ 8 49.6% Advanced Mathematical Concepts Unit 4 Answer Key Unit 4 Review 1. 35 27. Proof: S is defined as n 3 9 15 ... (6n 3) 3n2. Step 1: Verify that Sn is valid for n 1. Since S1 3 and 3(1)2 3, the formula is valid for n 1. 2. 1022 3. 3, 1, 5, 9 102 4 ᎏ 4. ᎏ 9375 Step 2: Assume that Sn is valid for n k and derive a formula for n k 1. Sk ⇒ 3 9 15 ... (6k 3) 3k2 Sk1 ⇒ 3 9 15 ... (6k 3) [6(k 1) 3] 3k2 [6(k 1) 3] 3k2 6k 3 3(k2 2k 1) 3(k 1)2 The formula gives the same result as adding the (k 1) term directly. Thus, if the formula is valid for n k, it is also valid for n k 1. Since the formula is valid for n 1, it is also valid for n 2. Since it is valid for n 2, it is also valid for n 3, and so on, indefinitely. Thus, the formula is valid for all positive integral values of n. 5. ᎏ43ᎏ 6. does not exist 7. 0 8. 4 9. 2 10. ᎏ43ᎏ 11. divergent 12. convergent 13. convergent 14. 2(1) 2(2) 2(3) 2(4) 2(5) or 30 15. [2(1)2 1] [2(2)2 1] [2(3)2 1] [2(4)2 1] [2(5)2 1] [2(6)2 1] [2(7)2 1] or 287 16. [3(2) 6] [3(3) 6] [3(4) 6] [3(5) 6] [3(6) 6] [3(7) 6] [3(8) 6] or 63 17. 3冢ᎏ21ᎏ冣0 3冢ᎏ21ᎏ冣1 3冢ᎏ21ᎏ冣2 3冢ᎏ21ᎏ冣3 38ᎏ 1 3冢ᎏ21ᎏ冣4 3冢ᎏ21ᎏ冣5 3冢ᎏ21ᎏ冣6 or ᎏ 64 18. 61,236x6 28. Proof: Sn ⇒ 5 n 1 4r for some integer r Step 1: Verify that Sn is valid for n 1. S1 51 1 or 4. Since 4 4 1, Sn is valid for n 1. Step 2: Assume that Sn is valid for n k and show that it is also valid for n k 1. Sk ⇒ 5 k 1 4r for some integer r. Sk 1 ⇒ 5 k1 1 4t for some integer t. 5 k 1 4r 5(5 k 1) 5(4r) 5 k1 5 20r 5 k1 1 20r 4 5 k1 1 4(5r 1) Thus, 5k1 1 4t, where t (5r 1), is an integer, and we have shown that if Sk is valid, then Sk1 is also valid. Since Sn is valid for n 1, it is also valid for n 2, n 3, and so on, indefinitely. Hence 5n 1 is divisible by 4 for all positive integral values of n. 29. 60,480 30. 840 31. 28 32. 6 19. 59,136x6y6 20. 5.41 21. 0.74 38. ᎏ25ᎏ 1ᎏ 39. ᎏ 13 40. ᎏ29ᎏ 3ᎏ 41. ᎏ 10 1ᎏ 1 42. ᎏ 850 5ᎏ 43. ᎏ 1296 44. ᎏ15ᎏ 8 45. ᎏ13ᎏ 4ᎏ 5 46. ᎏ 512 4ᎏ 7 47. ᎏ 128 48. 57 49. 77.45 50. 77 51. 77 52. 9.595 53. 9 54. 12.65 55. 99.7% 56. 0.1585 57. 0.576 58. 63.1670.84 59. 0.2260.274 60. 0.8 61. about 0.59 62. about 0.81 22. 4, 13, 40 33. 120 patterns 63. about 1.30 23. 1, 4, 11 34. 252 teams 64. 48.71–51.29 35. 60 ways 65. 98.45–101.55 36. 30 committees 66. 18.628–21.372 24. ᎏ12ᎏ, 2, ᎏ12ᎏ 25. i, 5i, 13i 26. 6 i, 12 5i, 24 13i 37. 2520 ways © Glencoe/McGraw-Hill A15 Advanced Mathematical Concepts Unit 4 Answer Key Unit 4 Test 4 1. (continued) 冱 (23 6k) 9. 20,160 k0 10. convergent 27. mean: 61.75; median: 56; mode: 53 2. 49.65% 11. 0.5 3. 28. 16; 8 Proof: Sn is defined as n(n 1)(2n 1) 12 22 32 . . . n2 ᎏ6ᎏ 12. 10,080 1(1 1)(2 1 1) 1, Since S1 1 and ᎏᎏᎏ 13. convergent the formula is valid for n 1. Step 2: Assume that Sn is valid for n k and derive a formula for n k 1. 14. 1, i, 1 2i Step 1: Verify that Sn is valid for n 1. 6 Sk ⇒ 12 22 32 ... k(k 1)(2k 1) ᎏᎏ 6 k2 Sk1 ⇒ 1 2 3 . . . k2 (k 1)2 2 2 2 k)(2k 1) 6(k2 2k 1) ᎏᎏᎏᎏ 6 4ᎏ 30. ᎏ 11 15. ᎏ14ᎏ 31. 197 k(k 1)(2k 1) ᎏ6ᎏ (k 1)2 (k2 1ᎏ 29. ᎏ 221 6ᎏ 4 16. ᎏ 125 2k3 9k2 13k 6 ᎏᎏᎏ 6 (k 1)(2k2 7k 6) ᎏᎏᎏ 6 (k 1)(2k 3)(k 2) ᎏᎏᎏ 6 (k 1)[(k 1) 1][2(k 1) 1] ᎏᎏᎏᎏ 6 The formula gives the same result as adding the (k 1) term directly. Thus, if the formula is valid for n k, it is also valid for n k 1. Since the formula is valid for n 1, it is also valid for n 2. Since it is valid for n 2, it is also valid for n 3, and so on, indefinitely. Thus, the formula is valid for all positive integral values of n. 4. 128 17. x3 6x2y 12xy2 8y3 18. 0.375 32. 13.55% 33. ᎏ3ᎏ 10 19. 20 20. 10; 20.5, 30.5, 40.5, 50.5, 60.5 34. 0.36; 35.0736.93 21. 1.95 35. 128.05131.25 22. 2, 2, 2 36. 68.3% 23. does not exist 5. ᎏ1ᎏ 21 37. 0.0225 24. ᎏ53ᎏ 25. 210 6. ᎏ5ᎏ 4 7. 20 8. true © Glencoe/McGraw-Hill 26. 38. 0.25 stem leaf 4 2 5 1339 6 1 7 5 10 0 4|2 42 39. 9.35510.645 A16 Advanced Mathematical Concepts 40. about 9.5910.41 BLANK BLANK BLANK BLANK