DIGITAL FINAL PROOF
Math Concept Reader
The Truth About Pi
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DIGITAL FINAL PROOF
Math Concept Reader
The Truth About Pi
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DIGITAL FINAL PROOF
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Math Concept Reader
The Truth About Pi by Aenea Mickelsen
Copyright © Gareth Stevens, Inc. All rights reserved. Developed for Harcourt, Inc., by Gareth Stevens, Inc. This edition published by Harcourt, Inc., by agreement with Gareth Stevens, Inc. No part of this publication may be reproduced or transmitted in any form or by any means, electronic or mechanical, including photocopy, recording, or any information storage and retrieval system, without permission in writing from the copyright holder. Requests for permission to make copies of any part of the work should be addressed to Permissions Department, Gareth Stevens, Inc., 330 West Olive Street, Suite 100, Milwaukee, Wisconsin 53212. Fax: 414-332-3567. HARCOURT and the Harcourt Logo are trademarks of Harcourt, Inc., registered in the United States of America and/or other jurisdictions. Printed in the United States of America ISBN 13: 978-0-15-360207-8 ISBN 10: 0-15-360207-4 1 2 3 4 5 6 7 8 9 10 175 16 15 14 13 12 11 10 09 08 07
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Chapter 1:
The Amazing World of Pi Toward the end of the afternoon on Tuesday, Mr. Griffin asks the students in his class to think about circles again. That morning they reviewed circumference and diameter of circles. Now Mr. Griffin wants to talk about the ratio pi. “The ratio pi has fascinated people for thousands of years,” he tells the class. “For more than 4,000 years, people have known that the ratio of the circumference of a circle to its diameter is pi. While no one knows for certain who first calculated pi, we do know that Ancient Greek and Chinese mathematicians used this value. Some mathematicians think that the Egyptians used pi when they built the pyramids.” Mr. Griffin explains that pi is an irrational number. That means that it cannot be written as the ratio of two integers. The digits after the decimal do not terminate, meaning there is not a countable number of digits in pi. Mr. Griffin also points out that the digits in pi do not repeat, nor do they occur in a repeating pattern. Mathematicians who have used supercomputers to calculate pi have not found even a simple repeating pattern.
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While the class discusses pi, Mr. Griffin writes just a part of its value on the board.
Mr. Griffin shares some other interesting pi facts with his class. People in the 1800s were able to calculate pi to about 1,000 digits. That was before they had calculators and computers to help them. They did their computations by hand. In 1999, Dr. Yasumasa Kanada at the University of Tokyo calculated 206,158,430,000 decimal digits of pi. Then, in 2002, he and his team broke its own world record by calculating more than six times that, or 1.2411 trillion decimal digits. Mr. Griffin tells his students that a trillion is a million million or 1,000,000,000,000. Calculating the decimal digits of pi isn’t the only way people have set records. Mr. Griffin tells the class about a Japanese man who memorized 83,431 digits of pi. Akira Haraguchi set that record on July 2, 2005. Reciting all of those digits took him many hours. Mr. Griffin grins and announces that any student who memorizes 25 digits or more will get bonus math class points. They don’t have to go as high as 83,000, though!
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1.2 cm
5.0 m
C ≈ 3.8
C ≈ 15.7
The circumference of a circle divided by its diameter is equal to pi, or approximately 3.14.
A fun thing some people do with the number pi is to find their birthday within the decimal digits. “A computer program will do it for you,” Mr. Griffin says as he shares with the class where to find his birthday. He was born on October 6, 1964, which can also be written as 10/6/64. The number 10664 occurs in pi after 177,303 decimal digits. He promises the class that the next morning they can each enter their birthdays in the online calculator to find out where they occur in pi. Mr. Griffin turns on his computer and the projector so the class can see an image on his screen. The image shows two circles, one that is small and hard to see, and another that is much larger. First he looks at the circumference and C = π. Together diameter of the small circle and writes — d the class does the math, and the students discover that the equation is true. Circumference divided by diameter equals pi, or approximately 3.14. The students then do the math for the larger circle. They get exactly the same result!
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Diameter Circumference
C = π is true of any circle—even a giant Ferris The equation — d wheel.
As his class is getting ready to leave for the day, Mr. C = π is true Griffin tells everyone that the equation — d for any circle. Sometimes rounding causes the digits in the quotient to be a bit different than pi, because of the rounding that might happen in the measurements of the circumference and diameter. Even if the measurements aren’t exact, the quotients should still be a little bit more than three. The equation is even true for man-made circles like Ferris wheels, Mr. Griffin tells his students. The students gather their backpacks and file out of the classroom. Two of the students, Grant and Courtney, live next door to each other. They walk home from school together most days. While they walk the three blocks to their houses, they discover that they are both determined to memorize at least 25 digits of pi in order to get extra points Mr. Griffin promised. They agree to help each other recite the digits. Grant tells Courtney that he is curious about Ferris wheels and wants to see if what Mr. Griffin said about the relationship between the circumference and the diameter of a circle is true.
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Chapter 2:
Ferris Wheels Around the World After he says goodbye to Courtney, Grant walks in his front door. His dad greets him as he strolls into the kitchen. Grant tells his dad what he learned about circles and about pi. He asks his dad if he will help him investigate Ferris wheels and find out whether what Mr. Griffin said about pi holds true for all circles. Together, they go to the computer and begin to search the Internet for information about Ferris wheels. As they search, Grant and his dad discover all kinds of information about the history of Ferris wheels. They learn that the World’s Colombian Exposition, held in Chicago in 1893, commemorated the 400th anniversary of Columbus’s landing in America. The World’s Colombian Exposition was also called the Chicago World’s Fair. The people in charge of planning the fair wanted to create a structure to rival the famous Eiffel Tower. The Eiffel Tower was built in 1889 for the Paris World’s Fair, which honored the 100th anniversary of the French Revolution.
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George Washington Gale Ferris created the Ferris wheel for the 1893 Chicago World’s Fair at the urging of Daniel H. Burnham.
Daniel H. Burnham was a famous architect from Chicago who had helped to design some of the earliest skyscrapers. He was in charge of finding a suitable design for the new structure for the Chicago World’s Fair. One evening at a banquet for engineers, he expressed his frustration at not having found anything. Someone in the crowd had an idea and doodled a design on a napkin during the dinner. That someone was George Washington Gale Ferris. He was an engineer and a bridge builder who owned his own company, G.W.G. Ferris & Co., and he had experience inspecting, testing, and erecting large steel structures. Merry-go-rounds were popular carnival rides in the 1800s. Ferris decided to design a kind of vertical merry-go-round that he hoped would be equally popular. He knew the ride had to be gigantic since he was competing with the famous Eiffel Tower.
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Ferris had only a little more than four months to raise funds and build his show-stopping amusement ride. The wheel used more than two thousand tons of steel.
People did not know what to think of Ferris’s design, so the project did not get started until December 16, 1892. The final product needed to be ready by May 1, 1893. That meant Ferris had a little over four months to raise the $355,000 needed to pay for the wheel. He also had to locate, construct, and assemble more than two thousand tons of steel for the Ferris wheel. By the end of March 1893, the Ferris wheel had been built in Detroit, Michigan, and transported to Chicago. It took 150 railroad cars to hold all of the pieces. At the time, the Ferris wheel’s 45-foot axle (the bar on which the wheel rotates) weighed 45 tons and was the largest piece of steel ever forged. William F. Gronau was Ferris’s partner. He had the responsibility of putting the wheel together. The diameter of the Ferris wheel was about 262 feet–about the height of a 25-story building! Two 140-foot steel towers supported it. The circumference of the wheel was approximately 825 feet. Each of the 36 cars on the Ferris wheel could hold 60 people. That meant about 2,160 people could ride at the same time.
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London, England, is the home of the landmark London Eye Ferris wheel.
Grant enters these measurements into the formula for pi. He calculates that for the original Ferris wheel, the relationship between the circumference and the diameter was a number a bit greater than three.
C = 825 ≈ 3.14885 — d 262
Next, Grant and his dad search for information about another Ferris wheel called the London Eye. The London Eye is a landmark in London, England, that was originally planned as part of the millennium celebration. People were supposed to be able to ride the London Eye on New Year’s Eve, 1999. There were some technical difficulties, however, so it wasn’t until three months later that people were finally able to climb on board for a ride. The diameter of this enormous wheel is about 135 meters, while its circumference is 424 meters. The London Eye has 32 capsules that can each carry as many as 25 people. A complete revolution on the London Eye takes about 30 minutes. C = π and plug in the Grant and his dad use the formula — d London Eye dimensions. 424 ≈ 3.14 135 The equation is true again! It seems that Mr. Griffin was right about pi.
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The Cosmo Clock in Yokohama, Japan, rises 369 feet above the ground.
Grant searches some more and finds two huge Ferris wheels in Japan. One is called the Cosmo Clock and is found in Yokohama, Japan. He reads that it rises 369 feet above the ground and has a diameter of 328 feet. Grant cannot find a circumference measurement for the Cosmo Clock. His dad explains that they can figure out this Ferris wheel’s circumference by using a different form of the equation. Since circumference divided by diameter equals pi, then another form of the equation that would work is pi times diameter equals the circumference. Grant and his dad do the math. They agree they will use 3.14 for π. C = πd C ≈ 3.14 x 328 C ≈ 1,029.92 The circumference of the Cosmo Clock must be about 1,029 feet. The Sky Dream Fukuoka is another Ferris wheel in Japan. Grant and his dad are able to find the diameter measurement of this ride, but not the circumference. The diameter is about 112 meters so they multiply this value by 3.14 and find that the circumference is about 351.68. The Sky Dream Fukuoka has a circumference of about 352 meters. 10
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The Prater Ferris wheel in Vienna, Austria, is more than 100 years old.
Grant finds a Ferris wheel called the Prater in Vienna, Austria, that was built more than 100 years ago. Despite its age, the Prater is still in use. Grant is excited to find measurements for both the diameter and the circumference of the big wheel. Quickly, he enters the C = π. The diameter of measurements in the formula — d the Prater is about 60.94 meters and the circumference is approximately 191.35 meters. 191.35 ≈ 3.14 60.94 Grant discovers that using more precise measurements for the circumference and diameter helps the quotient come closer to pi. Grant decides to look for the largest Ferris wheel in the United States. He finds information about the Texas Star at Fair Park in Dallas, Texas. The Texas Star is the largest Ferris wheel in all of North America. It has a diameter of about 212 feet and it holds as many as 260 people. The wheel’s circumference is about 665.5 feet. Grant divides 665.5 by 212 and calculates that, once again, the ratio is a number very close to 3.14. 11
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Chapter 3:
Circles at Home Grant is pleased that his research has been so successful. Now he wonders what other circles he can measure and test. He knows that the equation for pi works for big circles like Ferris wheels, but he’s not sure if it holds true for smaller circles. Grant slowly walks around his house, keeping his eyes open for circles to measure. When he steps into the garage, he notices his bike hanging from its mount. A bike tire would be a perfect way to test pi on smaller circles! Together, Grant and his dad pull the bike off of its mount and measure the diameter of the bike’s front tire. They find that it is about 26 inches across. Next, they carefully measure the circumference, with one person holding the measuring tape in place while the other person slowly winds it around the tire. That measurement is about 81.7 inches. They compute that 81.7 divided by 26 is a number very close to 3.14. It doesn’t seem to matter if they measure big circles or small ones. The ratio between a circle’s circumference and its diameter is always the same. 12
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Grant used pi to figure out the circumference and diameter of a drum he got as a gift from his grandmother.
By this time, Grant is sure that Mr. Griffin is correct about pi, but he still wants to measure one more household circle. He walks around his house again. In his room he sees the drum his grandmother sent him from one of her trips. He decides to measure the circumference and diameter of one end of his drum. He uses the standard side of his measuring tape and finds that the circumference of the end of his drum is about 50.25 inches. He stretches the measuring tape across the drum to find that its diameter is 16 inches. With his C = π, he plugs in the numbers. formula — d 50.25 ≈ 3.14 16 Grant also knows that circumference is related to radius. Out of curiosity, he uses the formula C = 2πr. When he does the calculation his answer is: C ≈ 2 x 3.14 x 8 C ≈ 50.25 He enjoys proving once again that the ratio really works. 13
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Courtney used a string to measure the circumference and diameter of the sound hole in her guitar.
As Grant and Courtney walk to school the next day, they discover that they both researched the formula C = π. Courtney tells Grant that she measured the sound — d hole in her guitar, and when she did the calculations she got a number very close to pi. Grant asks her how she managed to measure the circumference of the hole. Courtney explains her mom helped her solve that problem. Courtney’s mom took a piece of string and measured the hole with that. Courtney then marked and measured the string to find the circle’s circumference. As they walk, Grant and Courtney also work on memorizing the digits of pi. By the time they get to school, they have each memorized more than 15 digits. They hope that by tomorrow they will be ready to recite the 25 digits to Mr. Griffin for the bonus points. After the bell rings and they join their class, Grant and Courtney discover that others went home and investigated the ratio for pi, too.
14
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Students measured circles found all around their homes to find the ratio pi.
Mr. Griffin is thrilled that so many students investigated circles. He asks the class to describe what circles they found at home and how they measured them. Scott tells the class that he measured his mom’s favorite mixing bowl in the kitchen and that the circumference was 48 inches. Sure enough, Scott said he found that when he divided 48 by 3.14, he calculated 15.3 inches for the diameter. That was almost exactly what the tape measure showed. Other students had similar experiences when they tried measuring household circles. Shari says she measured several wheels on her little brother’s toys, and every one of them proved that the relationship between the circumference and the diameter is a number a bit larger than three. Mr. Griffin asks his class to talk about what they have learned. The students agree that pi remains constant, no matter what circumference or diameter a circle has, no matter how big or small the object—no matter what.
15
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Glossary axle a shaft or bar on which a wheel rotates circumference the distance around a circle diameter a line segment through the center of a circle, with endpoints on the circle Ferris wheel an amusement park ride consisting of a huge revolving wheel carrying seats irrational number a number that cannot be written as a ratio of two integers. One example of an irrational number is the ratio pi. millennium a period of 1,000 years. A millennium is also the celebration of a 1,000th anniversary. pi the ratio of a circumference of a circle to its diameter radius a line segment with one endpoint at the center of a circle and the other endpoint on the circle ratio a comparison of two numbers or quantities
Photo credits: cover, title page © Oswald Eckstein/zefa/Corbis; p. 5 © Paul Almasy/Corbis; p. 7 (left) Ferristree.com; pp. 7 (center, right), 8 Library of Congress; p. 9 © Peter Adams/ Corbis; pp. 10, 13 © Corbis; p. 11 © Barry Lewis/Corbis; pp. 14, 15 Russell Pickering.
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Think and Respond 1. The tire of a race car has a circumference of about 87.4 inches and a diameter of 27.83 inches. What is the ratio of the circumference to the diameter rounded to the nearest hundredth? 2. One of the paint cans in Grant’s garage has a diameter of 3.12 inches and a circumference of 9.81 inches. What is the ratio of the circumference to the diameter? Round your answer to the nearest hundredth. 3. A large truck used in the copper mines uses tires with a diameter of about 153 inches. What is the circumference of a tire that size? Use 3.14 for π.
4. Explain how you could find the circumference of a circle if you knew its diameter.