Practical Algebra: A Self-Teaching Guide
By Bobson Wong, Larisa Bukalov and Steve Slavin
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About this ebook
The most practical, complete, and accessible guide for understanding algebra
If you want to make sense of algebra, check out Practical Algebra: A Self-Teaching Guide. Written by two experienced classroom teachers, this Third Edition is completely revised to align with the Common Core Algebra I math standards used in many states. You’ll get an overview of solving linear and quadratic equations, using ratios and proportions, decoding word problems, graphing and interpreting functions, modeling the real world with statistics, and other concepts found in today’s algebra courses. This book also contains a brief review of pre-algebra topics, including arithmetic and fractions. It has concrete strategies that help diverse students to succeed, such as:
- over 500 images and tables that illustrate important concepts
- over 200 model examples with complete solutions
- almost 1,500 exercises with answers so you can monitor your progress
Practical Algebra emphasizes making connections to what you already know and what you’ll learn in the future. You’ll learn to see algebra as a logical and consistent system of ideas and see how it connects to other mathematical topics. This book makes math more accessible by treating it as a language. It has tips for pronouncing and using mathematical notation, a glossary of commonly used terms in algebra, and a glossary of symbols. Along the way, you’ll discover how different cultures around the world over thousands of years developed many of the mathematical ideas we use today. Since students nowadays can use a variety of tools to handle complex modeling tasks, this book contains technology tips that apply no matter what device you’re using. It also describes strategies for avoiding common mistakes that students make.
By working through Practical Algebra, you’ll learn straightforward techniques for solving problems, and understand why these techniques work so you’ll retain what you’ve learned. You (or your students) will come away with better scores on algebra tests and a greater confidence in your ability to do math.
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Practical Algebra - Bobson Wong
Practical Algebra
A Self-Teaching Guide
Third Edition
Bobson Wong
Larisa Bukalov
Steve Slavin
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ACKNOWLEDGMENTS
Writing a book is hard. Writing a book while teaching full-time during a pandemic is even harder. Fortunately, many people helped make this edition of Practical Algebra a reality. Our students' mathematical struggles and joys over the years inspired us to write this book. Conversations with our colleagues at Bayside High School and Math for America helped us develop many of the ideas and techniques we describe. Bayside students Juliana Campopiano and Queena Yue helped us proofread the text. The team at Desmos designed a powerful online graphing tool that we used to create the graphs in this book. The staff at John Wiley & Sons (especially Pete Gaughan, Christine O'Connor, Riley Harding, Julie Kerr, and Mackenzie Thompson) have been especially patient and supportive. Larry Ferlazzo introduced us to publishing math books, opening up countless opportunities. Finally, our spouses and children deserve special mention for tolerating our conversations about this book, peppering us with mathematical questions over the years, and helping to keep our work in perspective.
INTRODUCTION
What is algebra? You may associate it with solving equations such as 2x + 7 = 19. However, both the history of algebra and the way that it's taught today show that algebra is much more. For thousands of years, people solved algebraic problems without symbols such as x and +. By the 9th century, people including the Persian mathematician Muḥammad ibn Mūsā al-Khwārizmī had popularized the idea of using an algorithm (a set of well-defined instructions) to determine unknown quantities. In fact, the word algebra comes from the Arab word al-jabr, meaning the reduction,
from the title of al-Khwārizmī's most famous mathematical text, Kitāb al-jabr wa al-muqābalah. Symbolic notation didn't become widespread until European mathematicians such as François Viète and René Descartes developed them in the 16th and 17th centuries. Nowadays, algebra courses include not just equations but also functions (the special rules that define mathematical relationships) and real-world modeling with statistics. In short, today's algebra students must know how to understand word problems, make and interpret graphs, create and solve equations, and draw appropriate conclusions from data.
Not surprisingly, algebra makes many people nervous. Maybe you recall endless drills and elaborate procedures from years ago. Perhaps you're a middle school or high school student who's intimidated by the high level of abstract reasoning that's required. If so, you're not alone. We understand how you feel! For many years, we've taught all levels of high school math, so we have a lot of experience working with diverse learners. This book contains concrete strategies that help our students succeed. We strongly believe that people can get better at math if they have access to the right tools.
We wrote this book as a general introduction to algebra. We assume that you're familiar with basic arithmetic (adding, subtracting, multiplying, and dividing numbers) and fractions. If you're not comfortable with these topics, don't worry—we briefly review them in Chapters 1 and 2. Even if you are comfortable with them, we suggest that you look through these chapters anyway. We explain why these ideas work and how they're related to the algebraic ideas we discuss later on.
Each chapter in this book is divided into sections, with model examples and tips. At the end of each section, you'll find several exercises to help you practice and apply your skills. These exercises include what we call Questions to Think About (open-ended questions designed to help you think about important concepts) as well as dozens of word problems. Each chapter has a test with multiple-choice and open-ended questions. The solutions to all exercises and chapter tests are located at the end of each chapter.
As you work through this book, you'll see some important ideas about algebra that we emphasize:
Algebra is a language. We believe that many people find algebra intimidating because the words and symbols we use, such as polynomial, an, and f(x), literally look like a different language. In addition, we don't just write math, we also read and speak it. In the Reading and Writing Tips, we discuss how to write and pronounce mathematical symbols as well as how to use them in context. We also include a glossary of mathematical terms and symbols in the back of the book.
Algebra should make sense. We believe that algebra should be taught in a way that makes sense. In our experience, part of the reason why so many people suffer from math anxiety is that they see it as a collection of disjointed and confusing tricks. Throughout this book, we use techniques (such as the area model for multiplication) that relate to other mathematical topics, such as geometry and statistics. By making these connections, you can extend what you learned in one situation to another context, which will strengthen your mathematical skills and boost your confidence!
Algebra requires pictures. As we taught during the pandemic, we had to adjust our instruction. We couldn't be with our students in person, so they often had to teach themselves more independently. Incorporating graphs, tables, diagrams, and other images into our teaching helped our students make sense of math. Since this book is a self-teaching guide, we've included many visual strategies throughout this book.
Algebra requires technology. Calculators, computers, and other technology aren't just shortcuts for menial computations. They are now required for today's complex modeling tasks. Using technology helps us to see patterns more efficiently. Since each of these tools has vastly different user instructions, we don't include specific instructions for each device. Instead, we include Technology Tips that apply no matter what device you're using.
Algebra is a human endeavor. We believe that algebra should not be perceived as a set of rigid rules developed by a select group of people. In fact, as we note throughout this book, many mathematical concepts were developed in different cultures around the world over thousands of years. (We mention some of the more interesting stories in the Did You Know? callouts.) In addition, we recognize that making mistakes is a natural part of doing math. In the Watch Out! callouts, we point out many of the common errors that we've seen students make over the years so that you can avoid them!
We hope that as you work through this book, you'll find that algebra can be less intimidating and more meaningful than you originally thought.
— Bobson Wong and Larisa Bukalov
1
BASIC CONCEPTS
In this chapter, we review some of the concepts that students are typically expected to know before learning algebra. Although we don't have the space to fully develop these concepts, we point out some common mistakes and other important points that you should keep in mind. Even if you think that you know these topics, we recommend that you work through this chapter.
1.1 Addition, Subtraction, Multiplication, Division
Throughout this book, we use visual models to represent mathematical ideas. One important model is a number line, a line on which each point represents exactly one number. The numbers always increase from left to right. To show the scale, numbers are marked off at equal intervals. We draw an arrow at the end to indicate that the numbers extend infinitely in that direction.
Positive numbers, which we indicate with a + in front of the number, are numbers greater than 0. Negative numbers, which we indicate with a − in front of the number, are numbers less than 0. The word sign refers to the property of being positive or negative. The term signed numbers refers to numbers and their signs. Numbers that don't have a sign in front of them are understood to be positive.
On a horizontal number line (Figure 1.1), positive numbers lie to the right of 0, and negative numbers lie to the left of 0:
Did You Know?
The idea of positive numbers, negative numbers, and 0 may seem obvious to us now, but they actually developed around the world over thousands of years. By the 3rd century BCE, the Chinese were using counting rods of different colors to represent positive and negative numbers in their calculations. The 7th-century Indian mathematician Brahmagupta described rules in terms of fortunes
(positive numbers) and debts
(negative numbers). Ancient societies understood the concept of nothing ("we have no water"), but many cultures, such as the Egyptians, Romans, and Greeks, created complex mathematics without 0. The use of 0 didn't fully develop until the 5th century CE in India.
Figure 1.1 Number line
The absolute value of a number is its distance from 0 on a number line. Since the absolute value represents distance, it is always positive (unless we're talking about 0, which has an absolute value of 0). We use vertical bars to indicate absolute value. We read |+2| as the absolute value of positive two.
For example, |+15| is equal to 15, |−15| is equal to 15, and |0| is equal to 0. Two numbers that are the same distance from 0 on the number line but have different signs, such as +2 and −2, are opposites. Zero is an exception—the opposite of 0 is itself.
In math, we have four basic operations (mathematical processes performed on quantities to get a result): addition, subtraction, multiplication, and division. When we combine quantities with operations, we make an expression, such as 5 + 3 and |+15| − 4.
Watch Out!
We use the + and − symbols to represent both addition and subtraction and the sign of a number.
When + and − represent the sign of a number (which only occurs before a number), we read + as positive
and − as negative.
We never put a space between the symbol and the number, so negative 5
would be written −5, never − 5.
When + and − represent addition or subtraction (which only occurs between two numbers), we read + as plus
and − as minus,
and we put 1 space before and after the symbol. For example, 4 + 5, which is read as 4 plus 5,
means 5 is added to 4 to get a sum of 9.
The + and − symbols can represent both operations and signs in the same mathematical sentence. For example, +5 − −3 is read positive 5 minus negative 3,
not plus 5 minus minus 3.
Sometimes, we put parentheses around signed numbers to separate them from the addition or subtraction symbols, so we write +5 − −3 as (+5) − (−3). The parentheses are not pronounced.
You may recall working with number lines in elementary school. In this book, we also use squares to model signed numbers because they enable us to represent far more complicated ideas that we need to work with in algebra. To represent +1, we use a square whose area is +1. To represent −1, we use a square whose area is −1. (Don't worry about what a square with a negative area actually means
—it's just a model!) A square with area +1 and a square with area −1 have a total area of 0. We call this pair a zero pair. We can group zero pairs into rectangles (think of them as jumbo packs
of +1 or −1 squares) and use them to add signed numbers, as shown in Example 1.1:
Example 1.1 Evaluate −40 + 54.
Solution: When we evaluate an expression, we perform mathematical calculations to get a single number.
Mathematical representation of Evaluating −40 + 54.In this example, we use the = symbol (which is called an equal sign and read equals
or is equal to
). The equal sign means that the expression on its left has the same value as the expression on its right. A mathematical statement containing an equal sign is called an equation. To make your work easier to read, do one part of the calculation at a time and write each step on a different line, starting each line with the equal sign.
Watch Out!
One common mistake when writing several equations on one line is to ignore the meaning of the equal sign. For example, when evaluating 2 + 3 + 4, some students write: 2 + 3 = 5 + 4 = 9. This run-on
equation implies that 2 + 3, 5 + 4, and 9 are all equal, which isn't what we meant! Instead, write the following:
How to Add Signed Numbers
Determine the number with the larger absolute value.
Form zero pairs with the number with the smaller absolute value.
The remainder is the final answer, called the sum.
Addition and subtraction undo each other. For example, 5 + 3 − 3 equals 5. More formally, we say that addition and subtraction are inverse operations. This means that when we apply inverse operations on a number, the result is the original number. We can think of subtraction in terms of addition.
How to Subtract Signed Numbers
To subtract a positive number, add a negative number with the same absolute value, so 5 − 3 = 5 + (−3). The result, called the difference, is 2. (This models real-world behavior—adding debt lowers your net worth.)
To subtract a negative number, add a positive number with the same absolute value, so 5 − (−3) is the same as 5 + 3. The difference is 8. (This also models real-world behavior—removing debt raises your net worth.)
Example 1.2 illustrates how these rules work.
Example 1.2 Evaluate (−30) − (−46).
Solution:
Technology Tip
Many calculators have different buttons for subtraction and negative numbers. Often, the subtraction button is located next to the buttons for addition, multiplication, and division. To change the sign of an entry, they have a button labeled +/- or (−), where the - symbol on the button is shorter than the − symbol. Some calculators will return an error if you try to use the subtraction button to change the sign of a number, so be careful! In contrast, most software applications and mathematical websites don't differentiate between the negative and subtraction symbols, so entering 5 − −3 will result in the correct answer of 8.
When we multiply numbers, we add groups of the same size.
How to Multiply Signed Numbers
Multiply the absolute values of the factors (the numbers being multiplied).
If we multiply two numbers with different signs, the result (called the product) is negative.
If we multiply two numbers with the same sign, the result is positive.
We write the multiplication of 3 times 2 using one of these methods:
with × between the numbers, as in 3 × 2
with · between the numbers, as in 3 · 2
with parentheses around one or both numbers, as in (3)(2), 3(2), or (3)2
We recommend not using the × symbol in algebra because it can easily be mistaken for the letter x, which has a special meaning that we discuss in Chapter 3.
Since the area of a rectangle is the product of its length and width, then we can use rectangles to represent multiplication. This idea dates back thousands of years to ancient Mesopotamia, Greece, and the Middle East. Unfortunately, we can't realistically show the difference between positive and negative dimensions with a rectangle, so we label the dimensions with the appropriate signed numbers and use the multiplication rules that we described above to find the correct sign of the product.
Example 1.3 Represent (−10)(−5) using a rectangle and evaluate the result.
Solution: We can represent this as a rectangle whose dimensions are −10 and −5:
An illustration of a rectangle whose dimensions are −10 and −5.NOTE: We can also think of this as removing 5 groups of −10, which results in a net increase of 50.
Here are some special cases of multiplication:
Any number multiplied by 0 equals 0. For example, 4 groups of 0 is still 0.
A number multiplied by 1 equals itself. We can explain this conceptually by noticing that 1 group of 4 is just that number, so 4(1) = 4.
A number multiplied by −1 equals its opposite. For example, 4(−1) = −4 and −4(−1) = 4.
When we multiply a number by itself several times, we say that we raise it to a power. For example, we say that 2(2)(2)(2) equals 2⁴, which we read as two to the fourth power
or two to the fourth.
In this case, 2 is called the base (the number being multiplied) and 4 is the power or exponent (the number of times the base is being multiplied). The exponent is written above and to the right of the base. The term power refers to both the number 16 (what 2⁴ equals) as well as the exponent 4.
Here are some special cases for powers:
A number raised to the first power is equal to the number, so 2¹ = 2.
A number raised to the second power is squared, so 4² can be read as four squared,
four to the second power,
or four to the second.
(We get this term from the formula for the area of a square, which is the length of its edge multiplied by itself.)
A number raised to the third power is cubed, so 4³ can be read as four cubed,
four to the third power,
or four to the third.
(We get this term from the formula for the volume of a cube, which is the length of its edge multiplied by itself three times.)
A positive number raised to a positive power is always positive. We can surround the base with parentheses, so (3)⁴, (+3)⁴, and 3⁴ all represent the same quantity.
When we raise negative numbers to a power, we always surround the base with parentheses, so we write (−3)(−3)(−3)(−3) as (−3)⁴. If we raise a negative number to powers that are counting numbers, we see an interesting pattern in the signs:
(−3)¹ = −3
(−3)² = (−3)(−3) = +9
(−3)³ = (−3)(−3)(−3) = −27
(−3)⁴ = (−3)(−3)(−3)(−3) = +81
(−3)⁵ = (−3)(−3)(−3)(−3)(−3) = −243
We summarize this pattern as follows:
A negative number raised to an odd power is negative.
A negative number raised to an even power is positive.
Reading and Writing Tip
We have no easy way to express in words the difference between numbers like −3⁴ and (−3)⁴, since both can be pronounced as negative 3 to the fourth power.
We find that people pronounce (−3)⁴ as the quantity negative 3 to the fourth power,
parentheses negative 3 to the fourth power,
or "negative 3 (pause) to the fourth power." This is an example of a situation where mathematical symbols can communicate ideas more clearly and succinctly than words. Pay careful attention to how mathematical symbols are written. In the same way that a missing comma can completely change the meaning of a sentence, missing parentheses can give you a different answer!
When we divide numbers, we separate into groups of equal size. Multiplication and division are inverse operations.
How to Divide Signed Numbers
Divide the absolute values of the number that we divide (called the dividend) and the number that we divide by (called the divisor).
If we divide two numbers with different signs, the result (called the quotient) is negative.
If we divide two numbers with the same sign, the result is positive.
Division is often associated with fractions. A fraction is a quantity consisting of one number (called the numerator) divided by a nonzero number (called the denominator).
We write division using one of these methods:
Using the ÷ symbol (called the division symbol) between the two numbers, such as 8 ÷ 2
Using the / symbol between the two numbers, all written on the same line, such as 8/2
Writing one number on top of the other and separating the two with a fraction bar (sometimes called a vinculum), such as eight halves
All of these division examples are read as 8 divided by 2.
In this book, we prefer using the fraction bar to represent division. It provides the clearest separation of the quantities in division and minimizes the use of parentheses in more complicated mathematical statements.
When we use the ÷ or / symbol, the dividend appears before the symbol and the divisor appears after it. When we use a fraction bar, the dividend appears above it and the divisor appears below it. Figure 1.2 shows the terms associated with division:
An illustration of terms associated with division.Figure 1.2 Terms associated with division.
Some special cases of division deserve special attention:
Any number divided by 1 equals itself. For example, eight oneths , which means 8 divided into 1 group, equals 8.
Any number divided by 0 is meaningless. Another way of saying this is that a fraction can never have a denominator equal to 0. For example, StartFraction 8 Over 0 EndFraction has no meaning since there is no number that when multiplied by 0 would give a product of 8 (this would have to be true since multiplication and division are inverse operations).
Any nonzero number divided by itself equals 1. For example, eight eighths equals 1 .
Zero divided by a nonzero number equals 0. The fraction StartFraction 0 Over 8 EndFraction equals 0.
The reciprocal of a number is 1 divided by that number. The reciprocal of 8 is one eighth .
The product of a number and its reciprocal is 1. For example, 8 left-parenthesis one eighth right-parenthesis equals 1 .
Example 1.4 Represent StartFraction plus bold 6 Over negative bold 3 EndFraction using a rectangle and evaluate the quotient.
Solution: Using a rectangle, we can think of this as dividing a rectangle that has an area of +6 and a side length of −3. Using the rules for dividing two numbers with different signs, we conclude that the quotient must be negative, so the answer is −2.
Mathematic representation of dividing a rectangle that has an area of +6 and a side length of −3.Table 1.1 summarizes the steps for operations with signed numbers:
Table 1.1 Operations with signed numbers.
One final note: although understanding the rules for operations with signed numbers is important, you can always use technology to help you with these calculations.
Exercises
Write the pronunciation of each expression.
−8 − (−12)
(+1) − (+3)
(+6) + (−4)
(+7)(+15)
(−2)(−32)
(−6)⁴
Evaluate each expression:
|+7.5|
|−3|
|−889|
(+8) + (+5)
(+50) + (−10)
(−30) + (+20)
(−9) − (+5)
(−20) − (+30)
(−100) − (−40)
(+3)(−5)
(−3)(−7)
(−6)(+2)
(+2)³
(+6)²
(−7)²
−(−1)²
StartFraction plus 15 Over negative 3 EndFractionStartFraction 0 Over plus 9 EndFractionStartFraction negative 25 Over negative 5 EndFractionQuestions to Think About
What is the difference between the words plus
and positive
as they are used in math?
What are two examples of real-life quantities that could be modeled by adding negative numbers?
What are two examples of real-life quantities that could be modeled by subtracting negative numbers?
Is (−1,234,567,890,000,000)⁹⁹⁹ positive or negative? Explain.
1.2 Order of Operations
For many years, mathematicians didn't have a standardized set of rules for operations. When math education became more widespread in the 19th century, textbooks codified rules for what became known as the order of operations, the order in which mathematical operations should be performed. The growing popularity of computers in the last few decades has made the need for a standardized order of operations even more important.
In this book, we use the following convention (Figure 1.3) for order of operations:
GROUPING: First, evaluate everything surrounded by parentheses, brackets, fraction bars, absolute value symbols, and other grouping symbols, working from the innermost symbols outwards. To group numbers inside parentheses, we use square brackets or another set of parentheses: 2 − (3 − [5 − 1]) or 2 − (3 − (5 − 1)).
Schematic illustration of order of operations.Figure 1.3 Order of operations.
EXPONENTS: Next, evaluate exponents.
MULTIPLICATION/DIVISION: Next, when multiplication and division occur together, evaluate them left to right.
ADDITION/SUBTRACTION: Finally, when addition and subtraction occur together, evaluate them left to right.
Watch Out!
Some textbooks use the mnemonic PEMDAS (which stands for Parentheses, Exponents, Multiplication, Division, Addition, Subtraction) to remember the order of operations. We recommend you avoid using PEMDAS since it implies that multiplication should be done before division and addition before subtraction. If you prefer using a mnemonic, we suggest PEMA (Parentheses, Exponents, Multiplication, Addition). Unfortunately, PEMA doesn't include division and subtraction, so you'll have to remember which operations are inverse operations (multiplication and division, addition and subtraction) and perform them left to right.
Some problems can be solved more easily using a calculator:
Example 1.5 Evaluate 2(−5)²⁰.
Solution: The order of operations tells us that we need to evaluate the exponent first (in this case, the twentieth power) before the multiplication. The parentheses around −5 indicate that it, not −10 (which is the product of 2 and −5), is the base that is being raised to the twentieth power.
Multiplying −5 by itself 20 times is tedious, so we prefer using technology. To enter 2(−5)²⁰ into a calculator, we use the exponent button (usually marked ^ or xy), typing something like:
Mathematic representation of Multiplying.With technology, we get an answer that looks like 1.9073486328125E14. This is your device's way of displaying 1.9073486328125 × 10¹⁴. This number is written in scientific notation, which consists of a number at least 1 and less than 10 that is multiplied by a power of 10. Translating this into the more familiar standard notation, this number is 190,734,863,281,250.
Just because you can solve a problem with technology doesn't mean that it's easy! Entering complicated expressions on the calculator can be quite challenging, as shown in Example 1.6:
Example 1.6 Evaluate StartFraction bold 12 minus bold 3 bold-italic plus bold 4 left-parenthesis bold 3 right-parenthesis squared Over bold 33 minus bar minus bold 3 left-parenthesis bold 1 bold-italic plus bold 5 right-parenthesis bar EndFraction .
Solution: The fraction bar acts as a grouping symbol, separating the numerator from the denominator, so we calculate each separately. In the denominator, we work with grouping symbols from the inside out.
To enter this problem in the calculator, use the fraction tool if your device has one. This will put the numerator on top of the denominator, separated by a fraction bar. Doing so separates your numerator and denominator more clearly and reduces the likelihood of mistakes. Otherwise, you'd have to enter this problem on one line using many parentheses, which can be very confusing!
Technology Tip
When entering numbers into the calculator, keep the following in mind:
Use the +/− key, not the addition and subtraction keys, to make a number positive or negative.
Enter parentheses carefully. For example, (3)(2 + 1)² = 27, but (3(2 + 1))² = 81.
Use the exponent key (usually marked ^ or xy) to enter powers.
To enter fractions, use the fraction tool if your calculator has one. (See Example 1.6.)
Exercises
Evaluate each expression.
6 − 3 + 2
1 − 7 + 8
12 ÷ 2(3)
8 ÷ 2(2 + 2)
7 + 5(8)
9 + (−3)²
2(−4)²
4(−2)³
9 + |1 − 5|²
StartFraction 4 plus left-parenthesis 5 minus left-parenthesis 4 minus 7 right-parenthesis right-parenthesis Over bar negative 2 bar EndFractionStartFraction 2 cubed 3 squared Over 5 minus 1 plus 4 EndFractionleft-parenthesis StartFraction 5 left-parenthesis 16 plus 4 right-parenthesis Over 16 minus 2 left-parenthesis 3 right-parenthesis EndFraction right-parenthesis squaredQuestions to Think About
Use the order of operations to explain why 3(4)² is 48 and not 144.
Use the order of operations to explain why 5(1)² is 5 and not 25.
Use the order of operations to explain why −4² is negative and not positive. (HINT: −4² can be rewritten as (−1)(4)².)
1.3 Sets and Properties of Numbers
In math, we work with different groups, or sets, of numbers (Figure 1.4):
Counting numbers are the numbers we use to count: 1, 2, 3, 4, and so on.
Whole numbers are the counting numbers and zero: 0, 1, 2, 3, 4, and so on.
Schematic illustration of sets of numbers.Figure 1.4 Sets of numbers.
Integers are the whole numbers and their opposites: …, –3, –2, –1, 0, 1, 2, 3, …
Rational numbers are numbers that can be expressed as an integer divided by a nonzero integer.
Example 1.7 Is every integer a whole number? Explain.
Solution: No. Whole numbers are the counting numbers and 0 (0, 1, 2, 3, …). Integers are the whole numbers and their opposites (…, –3, –2, –1, 0, 1, 2, 3, …), and negative integers are not whole numbers.
Example 1.8 Is every whole number a rational number? Explain.
Solution: The whole numbers are the counting numbers and 0: 0, 1, 2, 3, and so on. The rational numbers are numbers that can be represented as an integer divided by a nonzero integer. Every whole number can be represented as itself divided by 1. Thus, every whole number is a rational number.
Table 1.2 summarizes important properties of numbers, some of which we have already mentioned:
In this table, a, b, and c are variables—letters or other symbols that represent quantities that can change in value. We will discuss another important property that relates to addition and multiplication in Chapter 3.
Table 1.2 Properties of Numbers