Integers

 

Integers are the building blocks of many mathematical concepts, representing whole numbers both positive and negative. Learning to work with integers effectively is crucial for students as they progress through their mathematical journey. Mastering the rules of integers and their operations allows students to tackle more complex concepts like algebra, number theory, and even real-life problem-solving involving gains and losses, elevation changes, and temperature variations.

In this blog post, we will explore integers in detail, focusing on their rules and operations. We'll also discuss the importance of the order of operations, commonly known as PEMDAS or BODMAS (depending on where you're learning), and how these rules apply when working with integers. Finally, we'll explain how the worksheets provided will help reinforce these concepts through practice and repetition.

What are Integers?

Integers are whole numbers that can be positive, negative, or zero. They do not include fractions or decimals. In mathematical terms, the set of integers is denoted by Z and includes:

{…, −3,  −2, −1, 0, 1, 2, 3,…}

• Positive integers: 1, 2, 3, …
• Negative integers: −1, −2, −3, …
• Zero: Neither positive nor negative, but part of the integer family.

Integers are essential in various aspects of mathematics, particularly in operations like addition, subtraction, multiplication, and division, as well as more advanced topics such as solving equations and inequalities.

Why Are Integers Important?

Understanding integers is foundational for grasping larger mathematical ideas. In real-world scenarios, integers are used to measure temperature changes (positive for increases, negative for decreases), bank account balances (positive for deposits, negative for withdrawals), and elevations (above or below sea level).

For students, a strong grasp of integer rules leads to confidence in higher-level math such as algebra, calculus, and data science. Moreover, as students’ progress through school, they will encounter negative numbers more frequently in mathematical problems, so early mastery of integers is essential.

Comparing Integers: Understanding Positive and and Negative Values 

When comparing integers, it's crucial to understand the relationships between positive and negative values. Positive integers are always greater than negative ones, but comparing two negative or two positive numbers requires a different approach. For visual and practical explanation, watch my video on comparing integers here: 

This video breaks down methods for accurately determining which integers is greater or lesser using number lines and examples. 

Rules of Integers

When working with integers, there are specific rules that govern their behavior, especially when performing operations such as addition, subtraction, multiplication, and division. Mastering these rules will ensure students can handle any problem involving integers.

1. Adding Integers

When adding integers, the sign of each number plays a critical role in determining the outcome. There are two key rules to remember:

• Same signs: If both integers have the same sign (both positive or both negative), simply add their absolute values (the number without its sign) and keep the common sign.

Example:

5 + 3 = 8 (Both are positive, so add and keep the positive sign)

(−5) + (−3) = −8 (Both are negative, so add and keep the negative sign)

• Different signs: If the integers have different signs, subtract the smaller absolute value from the larger absolute value, and keep the sign of the number with the larger absolute value.

Example:

(−5) + 7 = 2  (Subtract 5 from 7, and keep the sign of the larger absolute value, which is positive)

8 + (−12) = −4 (Subtract 8 from 12, and keep the sign of the larger absolute value, which is negative)

2. Subtracting Integers

Subtracting integers can be thought of as adding the opposite. The key rule is:

• To subtract an integer, add it’s opposite. This means changing the subtraction sign to addition and changing the sign of the number that follows.

Example:

7 – 5 = 7 + (−5) = 2

(−6) − (−8) = (−6) + 8 = 2

This rule simplifies subtraction into addition, making it easier to work through problems involving both positive and negative integers.

3. Multiplying Integers

The rules for multiplying integers are straightforward:

• Same signs: When multiplying two integers with the same sign, the result is positive.

Example:

4 × 5 = 20 (Both are positive, so the product is positive)

(−4) × (−5) = 20 (Both are negative, so the product is positive)

• Different signs: When multiplying two integers with different signs, the result is negative.

Example:

(−4) × 5 = −20 (One is negative, one is positive, so the product is negative)

 4 × (−5) = −20

Multiplication of integers follows a consistent pattern that is easy to remember once students practice with a few examples.

4. Dividing Integers

The rules for dividing integers mirror those for multiplication:

• Same signs: When dividing two integers with the same sign, the result is positive.

Example:

20 ÷ 4 = 5

(−20) ÷ (−4) = 5

• Different signs: When dividing two integers with different signs, the result is negative.

Example:

(−20) ÷ 4 = −5

20 ÷ (−4) = −5

When practicing division, it's essential for students to carefully track the signs of both integers to ensure they get the correct result.

Summary of Integer Rules

To summarize the rules of integers for quick reference:

• Addition: Same signs – add and keep the sign; different signs – subtract and keep the sign of the larger absolute value.
• Subtraction: Change the operation to addition and add the opposite.
• Multiplication/Division: Same signs – positive result; different signs – negative result.

Order of Operations: PEMDAS/BODMAS

When performing operations involving multiple steps, such as addition, multiplication, and parentheses, following the correct order of operations is critical. The order of operations dictates the sequence in which mathematical operations should be carried out to ensure consistency and accuracy.

The mnemonic PEMDAS helps students remember the order:

• Parentheses
• Exponents
• Multiplication and Division (from left to right)
• Addition and Subtraction (from left to right)

Alternatively, students might learn BODMAS:

• Brackets
• Orders (exponents)
• Division and Multiplication (from left to right)
• Addition and Subtraction (from left to right)

Why Order of Operations Matters

Without a standardized order of operations, math problems could be solved in different ways, leading to different answers. For example:

Consider the expression:

8 + 2 × 5

If you do the addition first, you'd get:

(8 + 2) × 5 = 10 × 5 = 50

However, following the correct order of operations, multiplication comes before addition:

8 + (2 × 5) = 8 + 10 = 18

So, the correct answer is 18, not 50.

Working with Integers and the Order of Operations

When solving problems involving integers, the rules of PEMDAS/BODMAS still apply. It’s essential to complete the operations in the correct order while also paying attention to the signs of the integers.

Consider this example:

(−3) × (4+2²) −5

Step-by-step solution:

1. Parentheses first: Solve inside the parentheses: 4+2²

4 + 4 = 8

2. Exponents next: There are no additional exponents outside the parentheses, so move on.
3. Multiplication: Multiply −3 × 8

(−3) × 8 = −24

4. Subtraction: Finally, subtract 5:

−24 −5 = −29

The correct answer is −29, showing how crucial it is to follow the order of operations while also applying the rules of integers.

Common Mistakes with PEMDAS/BODMAS

Students often make mistakes by rushing through multi-step problems or forgetting the correct sequence. Here are a few common errors:

1. Skipping Parentheses: Ignoring what's inside parentheses before tackling other operations can lead to incorrect answers.
2. Multiplying Before Exponents: Always handle exponents before moving on to multiplication or division.
3. Left to Right in Multiplication/Division and Addition/Subtraction: Some students incorrectly assume multiplication always comes before division or that addition always comes before subtraction. The key is to perform these operations from left to right.

By practicing with our worksheets, students will develop a strong understanding of the correct order of operations, ensuring they approach multi-step problems systematically.

Using Our Worksheets to Master Integers

To help students build a solid foundation in integers and the order of operations, our worksheets provide a variety of exercises designed for different learning levels. Here's how they can help:

• Rules of Integers: Worksheets focusing on addition, subtraction, multiplication, and division of integers provide clear examples and plenty of practice problems. These exercises ensure that students fully grasp how to work with both positive and negative numbers.
• Order of Operations: Our worksheets guide students through complex problems that require careful application of PEMDAS/BODMAS. With each problem, students will learn to manage multiple steps and integer operations without confusion.

Each worksheet is designed to reinforce the rules and order of operations through practice, repetition, and reflection. The goal is to ensure that students are confident in their ability to handle integers and can apply these skills in more advanced math.

Conclusion

Understanding integers and mastering the rules that govern them is crucial for any student progressing through mathematics. Whether you’re working with positive and negative numbers or learning the correct order of operations, building a strong foundation in these areas will set the stage for success in algebra and beyond.

The worksheets we’ve provided are a fantastic resource for students to practice and reinforce their understanding of integers, from basic operations to more complex problems involving the order of operations. By working through these exercises, students will gain confidence in their abilities, ensuring they can tackle any math challenge with ease.

So, take advantage of the worksheets, dive deep into the world of integers, and build the skills you need for future math success!

• Worksheet 1
  
• Worksheet 2