Grade 8
  1. Number Systems  1.1. Rational Numbers  1.2. Irrational Numbers  1.3. Real Numbers  1.4. Properties of Real Numbers  1.4.1. Commutative Property  1.4.2. Associative Property  1.4.3. Distributive Property  1.5. Representation on the Number Line  1.6. Operations on Real Numbers  1.6.1. Addition and Subtraction  1.6.2. Multiplication and Division  1.7. Rationalization  1.8. Exponents and Powers  1.9. Square Roots and Cube Roots
  2. Algebra  2.1. Algebraic Expressions  2.2. Identities and Simplification  2.2.1. Multiplying Binomials  2.2.2. Using Algebraic Identities  2.3. Factorization  2.3.1. Common Factors  2.3.2. Factorization by Grouping  2.3.3. Factorization of Trinomials  2.3.4. Special Products  2.4. Linear Equations in One Variable  2.4.1. Solving Linear Equations  2.4.2. Word Problems on Linear Equations
  3. Geometry  3.1. Understanding Quadrilaterals  3.1.1. Properties of Quadrilaterals  3.1.2. Types of Quadrilaterals  3.1.2.1. Parallelogram  3.1.2.2. Rectangle  3.1.2.3. Square  3.1.2.4. Rhombus  3.1.2.5. Trapezium  3.2. Constructions  3.2.1. Constructing Quadrilaterals  3.2.2. Constructing Bisectors  3.2.3. Constructing Angles  3.2.4. Constructing Triangles  3.3. Symmetry and Transformations  3.3.1. Reflection  3.3.2. Rotation  3.3.3. Translation  3.3.4. Symmetry in Patterns
  4. Mensuration  4.1. Area and Perimeter  4.1.1. Perimeter of Polygons  4.1.2. Area of Triangles  4.1.3. Area of Quadrilaterals  4.1.4. Area of Circles  4.2. Surface Area and Volume  4.2.1. Cubes  4.2.2. Cuboids  4.2.3. Cylinders  4.2.4. Cones  4.2.5. Spheres
  5. Data Handling  5.1. Organizing Data  5.2. Frequency Distribution Tables  5.3. Graphical Representation of Data  5.3.1. Bar Graphs  5.3.2. Histograms  5.3.3. Pie Charts  5.3.4. Line Graphs (added)  5.4. Probability  5.4.1. Introduction to Probability  5.4.2. Experimental Probability
  6. Coordinate Geometry  6.1. Cartesian Plane  6.2. Plotting Points  6.3. Coordinate System  6.4. Distance Between Points  6.5. Applications of Coordinate Geometry
  7. Introduction to Graphs  7.1. Linear Graphs  7.2. Applications of Graphs  7.3. Distance-Time Graphs  7.4. Speed-Time Graphs
  8. Comparing Quantities  8.1. Ratio and Proportion  8.2. Percentage  8.2.1. Increase and Decrease Percent  8.2.2. Discount in Percentage  8.2.3. Profit and Loss in Percentage  8.2.4. Simple Interest  8.2.5. Compound Interest
  9. Exponents and Powers  9.1. Laws of Exponents  9.2. Negative Exponents  9.3. Standard Form  9.4. Applications of Exponents
  10. Introduction to Squares and Square Roots  10.1. Properties of Square Numbers  10.2. Finding Square Roots  10.2.1. Prime Factorization Method  10.2.2. Division Method  10.3. Estimating Square Roots
  11. Introduction to Cubes and Cube Roots  11.1. Properties of Cube Numbers  11.2. Finding Cube Roots  11.2.1. Prime Factorization Method in Finding Cube Roots

Grade 8Introduction to Graphs


Linear Graphs


Introduction

In mathematics, graphs are used as a way to represent data, equations, and various kinds of relationships. Linear graphs, specifically, are graphs that depict linear equations. A linear equation, in its simplest form, describes a straight line in a coordinate system. The word 'linear' comes from the Latin word 'linearis', meaning relating to lines.

What are linear graphs?

A linear graph is a graphical representation of a linear equation. Linear equations are algebraic equations of the following types:

 y = mx + c

In this equation, y and x are variables, m is the slope of the line, and c is the y-intercept, which is the point where the line intersects the y-axis.

Equation of a line

Understanding the equation y = mx + c is important to creating and interpreting linear graphs. Each part of this equation tells you something about the line:

  • m (slope): Slope tells how steep the line is. It is calculated as the 'rise' over the 'run', or the change in y over the change in x, between two different points on the line.
  • c (y-intercept): The y-intercept is the y-coordinate of the point where the line intersects the y-axis (where x = 0).

Graphing a linear equation

You can follow these steps to draw a linear graph:

  1. Identify the slope (m) and y-intercept (c) from the linear equation.
  2. Plot the y-intercept on the graph.
  3. Use the slope to determine another point on the line.
  4. Through these points draw a line extended indefinitely in both directions.

Visual example

Example 1: Simple line graph

Consider the equation of a line:

 y = 2x + 3

Here, the slope m is 2, and the y-intercept c is 3. Let's plot it:

    Plot (0, 3) for the y-intercept,
    Move 2 units up and 1 unit to the right to mark another point at the base of the slope.
Y X (0,3) (1,5)

Example 2: Horizontal line

Consider the equation of the line:

 y = 4

This represents a horizontal line crossing the y-axis at 4.

Y X (x,4)

Example 3: Vertical line

Consider the equation of the line:

 x = -2

It represents a vertical line intersecting the x-axis at -2.

Y X (-2,y)

Understanding slope

The slope of a line tells us how the line goes up or down. Here are the different types of slopes you may encounter:

  • Positive slope: A line that goes up as you move from left to right. Example: Any line with m > 0.
  • Negative slope: A line that falls as you go from left to right, meaning m < 0.
  • Zero slope: A horizontal line where m = 0. Example: y = 4.
  • Undefined slope: A vertical line for which the slope is undefined. Example: x = -2.

Slope calculation

To determine the slope between two points on a line you use the following formula:

 M = (y2 - y1) / (x2 - x1)

where (x1, y1) and (x2, y2) are two different points on the line.

Example of calculating the slope

Find the slope of the line passing through the points (1, 2) and (3, 6).

    m = (6 - 2) / (3 - 1)
    m = 4 / 2
    m = 2

The slope of the line is 2.

Graphical characteristics of linear functions

Linear graphs have unique properties that distinguish them from nonlinear graphs:

  • Linear drawings create straight, no-curve lines.
  • They have a constant slope; this uniformity indicates a constant change with a uniform increase in x-values.
  • The domain of a linear graph is generally all real numbers (which allows the graph to extend to infinity on the x-axis), unless otherwise restricted in the context of a specific problem.

Applications of linear diagram

Linear diagrams are widely used in various fields due to their simplicity and clarity in depicting direct relationships:

  • Computer graphics: Linear algebra is used to model 2D and 3D space, which is important for rendering objects.
  • Physics: Used in calculating velocity and other rates involving simple, uniform motion.
  • Economics: cost analysis, determining supply-demand relationships, and optimizing profits.
  • Statistics: Regression lines, intended to show relationships between variables in a data model.

Representing linear graphs algebraically

Graphs provide visual interpretation, but algebra is another cornerstone method for working with linear equations. Here are the main algebraic forms:

  1. Slope-intercept form: y = mx + c, useful for quickly identifying the slope and y-intercept.
  2. Standard form: Ax + By = C; Facilitates calculations such as inspecting lines for parallel or perpendicular relationships.
  3. Point-slope form: y - y1 = m(x - x1), excellent for situations where you know the slope of a line and a point on the line.

Example: Converting between forms

Convert y = 2x + 3 to standard form:

    y – 2x = 3
    Multiply by -1: -y + 2x = -3
    Arrange: 2x – y = -3

The standard form is 2x - y = -3.

Solving linear equations

Solving involves finding all possible pairs of (x, y) that satisfy the given linear equation:

To solve y = 2x - 1:

  1. Substitute the value in place of x to find the corresponding y value.
  2. For example: If x = 0, then y = (2*0) - 1 = -1.
  3. If x = 1, then y = (2*1) - 1 = 1.
  4. Keep exploring as many as necessary to understand the behavior of the function.

Summary

In this detailed exploration of linear graphs, we have covered the basic concept of a linear equation and how it is represented graphically through linear graphs. We explored y = mx + c form, its components, and various ways to graph and manipulate linear equations.

Moreover, recognizing the arithmetic expression of a line helps us solve real-world problems effectively, and mastering the graphical representation can lead to better interpretative skills in various fields that rely heavily on linear relationships.


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Linear Graphs

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