Algebraic Expressions

Class 7 Foundation

About Lesson

10.1 Introduction

Simple Algebraic Expressions:
- Algebraic expressions like $x + 3$ , $y - 5$ , $4 x + 5$ , and $10 y - 5$ are examples of simple expressions.
- These expressions consist of variables (such as $x$ and $y$ ) combined with constants (like 3, -5, 4, 5, and -20) using operations like addition and subtraction.
Usefulness in Formulating Puzzles and Problems:
- Simple algebraic expressions help in creating and solving mathematical puzzles and problems.
- They serve as a foundation for understanding more complex algebraic concepts and real-life problem-solving.
Exposure in Class VII:
- In earlier classes, particularly in Class VI, students are introduced to the basic concepts of algebra.
- They learn to recognize and manipulate algebraic expressions, setting the stage for more advanced studies.
Importance of Expressions in Algebra:
- Algebraic expressions are a central concept in the study of algebra.
- Mastery of expressions is essential for progressing to more complex topics like equations, functions, and calculus.
Goals of This Chapter:
- Formation of Algebraic Expressions:
  - Understanding how variables and constants are combined using arithmetic operations to form algebraic expressions.
- Combining Algebraic Expressions:
  - Learning how to add, subtract, multiply, and divide expressions to form new expressions.
- Finding Values of Expressions:
  - Discovering methods to evaluate expressions for given values of variables.
  - This includes substituting specific numbers for variables and performing the necessary arithmetic operations.
- Applications of Algebraic Expressions:
  - Exploring how expressions are used in various mathematical contexts, including geometry (e.g., calculating areas and perimeters) and everyday mathematics (e.g., financial calculations, measurements).

10.2 How Are Expressions Formed?

Variables and Constants:
- Variables:
  - Represented by letters like $x, y, l, m,$ etc.
  - Variables can take various values; their values are not fixed.
- Constants:
  - Numbers with fixed values like 4, 100, -17.
Combining Variables and Constants:
- Variables and constants are combined using arithmetic operations (addition, subtraction, multiplication, and division) to form algebraic expressions.
- Examples:
  - $4 x + 5$ : Formed by multiplying the variable $x$ by the constant 4 and then adding the constant 5.
  - $10 y - 20$ : Formed by multiplying $y$ by 10 and then subtracting 20.
Expressions from Variables and Constants:
- Expressions are not limited to combinations of variables and constants but can also involve variables combined with other variables.
- Examples:
  - $x^{2}$ : Formed by multiplying $x$ by itself ( $x \times x = x^{2}$ ).
  - $2 y^{2}$ : Formed by multiplying $y$ by itself to get $y^{2}$ , then multiplying $y^{2}$ by 2.
  - $3 x^{2} - 5$ : Formed by multiplying $x$ by itself to get $x^{2}$ , then multiplying $x^{2}$ by 3 to get $3 x^{2}$ , and finally subtracting 5.
  - $x y$ : Formed by multiplying $x$ and $y$ together.
  - $4 x y + 7$ : Formed by multiplying $x$ and $y$ to get $x y$ , then multiplying $x y$ by 4 to get $4 x y$ , and finally adding 7.
Summary:
- Forming Expressions:
  - Algebraic expressions are formed by combining variables and constants using arithmetic operations.
- Operations:
  - Addition, subtraction, multiplication, and division are used to create expressions from variables and constants.
- Examples of Complex Expressions:
  - Expressions can involve variables multiplied by themselves, by constants, or by other variables.
- Understanding Terms:
  - Each part of an expression formed separately is called a term.
  - For example, in $4 x + 5$ , $4 x$ and 5 are terms.
  - Terms are combined to form algebraic expressions.

10.3 Terms of an Expression

Definition of Terms:
- Terms: Parts of an algebraic expression that are added together.
- Formation: Each term is formed separately and then combined to form an expression.
Examples of Terms:
- Expression: $4 x + 5$
  - Terms: $4 x$ and $5$
- Expression: $3 x^{2} + 7 y$
  - Terms: $3 x^{2}$ and $7 y$
Identifying Terms:
- Terms are separated by addition (+) or subtraction (−) signs.
- Example: In $4 x^{2} - 3 x y$ , the terms are $4 x^{2}$ and $- 3 x y$ .
Understanding Factors:
- Factors of a Term: Numbers and variables that multiply together to form a term.
- Examples:
  - $4 x^{2}$ has factors 4, $x$ , and $x$ .
  - $- 3 x y$ has factors -3, $x$ , and $y$ .
Tree Diagrams:
- Tree diagrams can help visualize the terms and their factors.
- Example:
  - Expression: $4 x^{2} - 3 x y$
    - Term: $4 x^{2}$
      - Factors: 4, $x$ , $x$
    - Term: $- 3 x y$
      - Factors: -3, $x$ , $y$
Coefficients:
- Definition: The numerical factor of a term.
- Examples:
  - In $5 x y$ , 5 is the coefficient.
  - In $- 7 x^{2} y^{2}$ , -7 is the coefficient.
General Use of Coefficients:
- Sometimes, a coefficient can be an algebraic factor or a product of several factors.
- Example:
  - In $5 x y$ , 5 is the coefficient of $x y$ .
  - In $10 x y^{2}$ , 10 is the coefficient of $x y^{2}$ .
Identifying Terms and Coefficients:
- Example 1: $x y + 4$
  - Term: $x y$ – Coefficient: 1
- Example 2: $13 - y^{2}$
  - Term: $- y^{2}$ – Coefficient: -1
- Example 3: $13 - y + 5 y^{2}$
  - Term: $- y$ – Coefficient: -1
  - Term: $5 y^{2}$ – Coefficient: 5
- Example 4: $4 p^{2} q - 3 p q^{2} + 5$
  - Term: $4 p^{2} q$ – Coefficient: 4
  - Term: $- 3 p q^{2}$ – Coefficient: -3
Practice Identifying Coefficients:
- Expressions and Coefficients:
  - $4 x - 3 y$ : Coefficient of $x$ is 4
  - $8 - x + y$ : Coefficient of $x$ is -1
  - $y^{2} x - y$ : Coefficient of $x$ is $y^{2}$
  - $2 z - 5 x z$ : Coefficient of $x$ is -5z
  - $4 x - 3 y$ : Coefficient of $y$ is -3
  - $8 + yz$ : Coefficient of $y$ is $z$
  - $y z^{2} + 5$ : Coefficient of $y$ is $z^{2}$
  - $m y + m$ : Coefficient of $y$ is $m$

10.4 Like and Unlike Terms

Definition:
- Like Terms: Terms that have the same algebraic factors.
- Unlike Terms: Terms that have different algebraic factors.
Example of Like Terms:
- In $2 x y - 3 x + 5 x y - 4$ :
  - $2 x y$ and $5 x y$ are like terms because they both have the factors $x$ and $y$ .
- Similarly, $- 3 x$ and $- 4$ are like terms because they both have no variables.
Example of Unlike Terms:
- In $2 x y - 3 x + 5 x y - 4$ :
  - $2 x y$ and $- 3 x$ are unlike terms because they have different algebraic factors.
  - Likewise, $2 x y$ and $- 4$ are also unlike terms.
Understanding Factors for Comparison:
- Factors such as variables and their powers are compared to determine if terms are like or unlike.
- Coefficients (the numerical part of a term) are not considered when determining likeness.
Importance in Simplifying Expressions:
- Identifying like terms is crucial when simplifying expressions through addition or subtraction.
- Like terms can be combined by adding or subtracting their coefficients while keeping their variables unchanged.
Example:
- In $3 x + 2 y - 5 x + 4 y$ :
  - $3 x$ and $- 5 x$ are like terms because they both have the factor $x$ .
  - $2 y$ and $4 y$ are also like terms because they both have the factor $y$ .
  - Therefore, the expression can be simplified to $(3 x - 5 x) + (2 y + 4 y)$ , which becomes $- 2 x + 6 y$ .
Practice Identifying Like and Unlike Terms:
- In $2 x y - 3 x + 5 x y - 4$ :
  - $2 x y$ and $5 x y$ are like terms.
  - $- 3 x$ and $- 4$ are like terms.
  - But $2 x y$ and $- 3 x$ are unlike terms.
General Rule:
- To determine if terms are like or unlike, compare the variables and their powers.
- If the variables and their powers are the same, the terms are like; otherwise, they are unlike.

10.5 Monomials, Binomials, Trinomials, and Polynomials

Definition:
- Monomial: An algebraic expression with only one term.
- Binomial: An algebraic expression with two unlike terms.
- Trinomial: An algebraic expression with three unlike terms.
- Polynomial: An algebraic expression with one or more terms.
Examples:
- Monomial: $4 x y$ , $- 5 a^{2} b$
- Binomial: $x + y$ , $3 m - 2 n$
- Trinomial: $2 x^{2} - x y + 1$ , $a^{3} + ab - 3 a$
Understanding Terms:
- Monomial: Consists of one term. Example: $4 x y$
- Binomial: Consists of two unlike terms. Example: $x + y$
- Trinomial: Consists of three unlike terms. Example: $2 x^{2} - x y + 1$
- Polynomial: Consists of one or more terms. Example: $4 x^{2} + 3 x y - 2 y$
Classification:
- Based on Number of Terms:
  - Monomial: 1 term
  - Binomial: 2 terms
  - Trinomial: 3 terms
  - Polynomial: More than 3 terms
Examples of Polynomials:
- $3 x^{2} + 2 x y - 5 y$
- $a^{3} + 4 a^{2} b - 2 a b^{2} + b^{3}$
Importance in Algebra:
- Polynomials are fundamental in algebraic expressions and equations.
- They are used to model various real-world situations and solve mathematical problems.
Practice Identifying:
- Monomial: $5 x^{2}$ , $- 3 ab$
- Binomial: $x - y$ , $2 m + 3 n$
- Trinomial: $2 x^{2} - x y + 1$ , $a^{3} + ab - 3 a$
- Polynomial: $4 x^{2} + 3 x y - 2 y$ , $x^{4} - 2 x^{2} + 3 x - 7$
Understanding Algebraic Expressions:
- Polynomials are used to represent relationships and solve equations in various fields, including physics, engineering, and economics.

10.6 Finding the Value of an Expression

Definition:
- Finding the value of an algebraic expression involves substituting specific values for the variables in the expression and evaluating the result.
Importance:
- Essential in various mathematical contexts, including solving equations, evaluating formulas, and solving real-world problems.
Example:
- Consider the expression $3 x + 2 y$ :
  - If $x = 4$ and $y = 5$ , we substitute these values into the expression:
    - $3 (4) + 2 (5) = 12 + 10 = 22$
  - Therefore, when $x = 4$ and $y = 5$ , the value of the expression $3 x + 2 y$ is 22.
Applications:
- Equation Solving: Used to verify if a particular value of a variable satisfies an equation.
- Geometry: Used in formulas to find the area, perimeter, volume, etc., of geometric shapes.
- Real-world Problems: Used to solve problems involving quantities that vary, such as cost, distance, time, etc.
Steps:
1. Substitute: Replace each variable in the expression with the given value.
2. Evaluate: Perform the arithmetic operations to find the result.
Example Problem:
- Problem: Find the value of the expression $2 x^{2} - 3 x y + 4 y$ when $x = 3$ and $y = 2$ .
- Solution:
  - Substitute $x = 3$ and $y = 2$ into the expression:
    - $2 (3)^{2} - 3 (3) (2) + 4 (2)$
  - Evaluate each term:
    - $2 (9) - 3 (6) + 8 = 18 - 18 + 8 = 8$
  - Therefore, when $x = 3$ and $y = 2$ , the value of the expression is 8.
Practice:
- Given an expression and specific values for the variables, students can practice finding the value of the expression by substitution and evaluation.
Real-world Examples:
- Geometry: Finding the area of a rectangle given its length and width.
- Physics: Using formulas to calculate velocity, acceleration, force, etc.
- Finance: Calculating interest, discounts, profits, etc., in business applications.

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10.1 Introduction

10.2 How Are Expressions Formed?

10.3 Terms of an Expression

10.4 Like and Unlike Terms

10.5 Monomials, Binomials, Trinomials, and Polynomials

10.6 Finding the Value of an Expression

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