Quadratic Inequalities
Quadratic inequalities are a type of algebraic inequality that involves quadratic expressions. A quadratic inequality looks like ax2+bx+c>0, ax2+bx+c<0, ax2+bx+cβ₯0 or ax2+bx+cβ€, where a, b, and c are constants, and aβ 0.
It is a fundamental concept in mathematics, particularly in algebra and calculus. They involve expressions containing quadratic polynomials and inequality signs. It is often required in solution sets that fulfill specific criteria. Lets know more about Quadratic Inequalities in detail below.
Quadratic Inequalities
Quadratic Inequalities are mathematical expressions involving quadratic equations that contain inequality symbols such as β , <, >, β€, or β₯. They are represented in the form ax2 + bx + c < 0, > 0, β€ 0, or β₯ 0, where βaβ, βbβ, and βcβ are constants, and βxβ is the variable raised to the power of 2.
These inequalities present relationships between quadratic functions and describe regions or intervals where the quadratic expression is less than, greater than, less than or equal to, or greater than or not equal to a specified value. Solving quadratic inequalities involves determining the sets of values for which the given inequality holds true, considering various algebraic methods and graphical interpretations. If there is an equal to sign present we call it an Equation.
Quadratic Inequalities Definition
An expression where a quadratic expression ax2 + bx + c is equated to any variable of degree 2 or less or number with inequality symbol such as β , <, β€, >, β₯ is called Quadratic Inequality. For Example β 3x2 + 2x β₯ 0
Standard Form of Quadratic Inequalities
A quadratic inequality can assume any of the following standard forms:
- ax2 + bx + c > 0
- ax2 + bx + c < 0
- ax2 + bx + c β₯ 0
- ax2 + bx + c β€ 0
Quadratic Inequalities Example
Following table mentions the Example of Quadratic Inequalities
Quadratic Inequalities | Meaning |
---|---|
3x2 + 2x β 0 | 3x2 + 2x is not equal to zero |
5x2 + 2x > 0 | 5x2 + 2x is greater than zero |
x2 β 2x < 9 | x2 β 2x is less than 9 |
x2 β 7x β₯ 2 | x2 β 7x is greater than or equal to 2 |
x2 β 3x β€ 5 | x2 β 3x is less than or equal to 5 |
How to solve Quadratic Inequality?
We can solve a Quadratic Inequality using following steps:
Step 1. Set the quadratic expression: Write the quadratic inequality in the form ax2 + bx + c < 0, > 0, β€ 0, or β₯ 0.
Step 2. Factor or find roots: Factorize the quadratic expression or use the quadratic formula to find the roots (if possible).
Step 3. Determine critical points: Identify critical points or values of βxβ where the inequality may change, considering the roots and the sign of βaβ.
Step 4. Create intervals: Use critical points to create intervals on the number line, dividing it into sections where the inequality might change.
Step 5. Choose test values: Select test values within each interval to check the inequalityβs validity. Use values like endpoints, zeros, or convenient numbers within each interval.
Step 6. Evaluate the inequality: Substitute the test values into the original inequality to determine if they satisfy the inequality.
Step 7. Determine solution regions: Identify intervals where the inequality holds true based on the test valuesβ outcomes.
Step 8. Express solution set: Present the solution set either as an inequality on the number line or in set notation, considering the intervals where the inequality is valid.
Solve Quadratic Inequalities
Solving Quadratic Inequalities means finding the value of x for which it satisfies the given inequality. We can solve a Quadratic Inequality using three methods:
- Graphical Method
- Algebraic Method
Graphical Method
In Graphical Method, we first draw the graph of the inequality and then find the solution of the given inequality using the graph. Lets see how to solve Quadratic Inequalities using the Graphical method with the help of an example.
Example: x2 β 3x β 4 > 0
Solution:
We can solve the above example using graphical methods
Step 1: Plotting the graph of the quadratic function y = x2 β 3x β 4
Finding the x-intercepts:
Given quadratic function: y = x2 β 3x β 4
To find the roots, solve for y = 0:
x2 β 3x β 4 = 0
Factorizing the equation or using the quadratic formula:
x2 β 4x + x β 4 = 0
x(x β 4) + 1(x β 4) = 0
(x β 4)(x + 1) = 0
Therefore, the roots are x = 4 and x = -1
Plotting the graph:
Step 2: Identifying regions where the graph lies above the x-axis (where y > 0)
We are looking for the regions where the quadratic function is positivee(y > 0).
The function is y = x2 β 3x β 4. We know the roots are x = 4 and x = -1.
Step 3: Determining the x-values within these regions to obtain the solution set
Based on the graph, the regions where y > 0 are:
β x < -1
β x > 4
Therefore, the solution set for x2 β 3x β 4 > 0 is x < -1 or x > 4.
This solution is derived from observing the parts of the graph where the quadratic function y = x2 β 3x β 4 is above the x-axis.
Algebraic Method
Algebraically we can solve a quadratic inequality using following three methods
- Factoring
- Quadratic Formula
- Completing the Square
Factoring
In Factoring, we split the given quadratic expression in product of its factors to find out the solution.
Example: Find out the solution for the inequality x2 β 3x β 4 > 0 using Factoring Method
Solution:
Given inequality: x2 β 3x β 4 > 0
Step 1: Factor the quadratic expression:
(x β 4)(x + 1) > 0
Step 2: Identify intervals based on the factors:
Interval I: x < -1
For x < -1, consider the factors (x β 4)(x + 1):
Pick a test point within the interval, say x = -2, substitute into (x β 4)(x + 1):
((-2) β 4)((-2) + 1) = (-6)(-1) = 6 > 0
The inequality holds for x < -1.
Interval II: -1 < x < 4
For -1 < x < 4, consider the factors (x β 4)(x + 1):
Pick a test point within the interval, say x = 0, substitute into (x β 4)(x + 1):
(0 β 4)(0 + 1) = (-4)(1) = -4 < 0
The inequality doesnβt hold for -1 < x < 4.
Interval III: x > 4
For x > 4, consider the factors (x β 4)(x + 1):
Pick a test point within the interval, say x = 5, substitute into (x β 4)(x + 1):
(5 β 4)(5 + 1) = (1)(6) = 6 > 0
The inequality holds for x > 4.
Therefore, the solution is x < -1 or x > 4.
Quadratic Formula
Use the quadratic formula to find the roots and determine the intervals where the expression is positive.
Example: Find the solution of the given inequality x2 β 3x β 4 > 0 using Quadratic Formula
Solution:
Step 1: Apply the quadratic formula to find the roots:
x = [3 Β± β((-3)2 β 4Γ1Γ(-4))]/(2Γ1)
x = [3 Β± β(25)]/2
x = [3 Β± 5]/2
Roots: x = 4 or x = -1
Step 2: Test intervals to determine where the expression is positive:
Interval I: x < -1 β (x2 β 3x β 4) > 0
For x < -1, consider the quadratic expression (x2 β 3x β 4):
Choose a test point, say x = -2, substitute into (x2 β 3x β 4):
((-2)2 β 3(-2) β 4) = (4 + 6 β 4) = 6 > 0
The inequality holds for x < -1.
Interval II: -1 < x < 4 β (x2 β 3x β 4) < 0
For -1 < x < 4, consider the quadratic expression (x2 β 3x β 4):
Choose a test point, say x = 0, substitute into (x2 β 3x β 4):
((0)2 β 3(0) β 4) = (-4) < 0
The inequality doesnβt hold for -1 < x < 4.
Interval III: x > 4 β (x2 β 3x β 4) > 0
For x > 4, consider the quadratic expression (x2 β 3x β 4):
Choose a test point, say x = 5, substitute into (x2 β 3x β 4):
((5)2 β 3(5) β 4) = (25 β 15 β 4) = 6 > 0
The inequality holds for x > 4.
Therefore, the solution is x < -1 or x > 4.
Completing the Square
In completing the square method, convert the quadratic expression into a perfect square trinomial to solve the inequality.
Example: Solve the given inequality x2 β 3x β 4 > 0 by using Completing the Square Method
Solution:
Step 1: Complete the square:
x2 β 3x β 4 = (x β (3/2))2 β 25/4
Step 2: Set up the inequality:
(x β (3/2))2 β 25/4 > 0
Step 3: Find the intervals where the inequality holds:
This gives two cases:
Case 1: x β (3/2) > 5/2
x > 8/2
x > 4
Case 2: x β (3/2) < -5/2
x < -2/2
x < -1
Therefore, the solution is x < -1 or x > 4.
Graphical Quadratic Inequalities
Graphing quadratic inequalities involves plotting the corresponding quadratic function and shading the region where the inequality holds true on the coordinate plane. The graph visually represents the solution set of the inequality.
To graph a quadratic inequality, first, plot the quadratic function y = ax2 + bx + c on the Cartesian plane. Determine the concavity based on the sign of βaβ. If βaβ is positive, the parabola opens upwards, and if βaβ is negative, it opens downwards. Locate the vertex of the parabola, determined by (-b/2a, f(-b/2a)), where βfβ represents the function.
Next, identify the critical points or roots (x-intercepts) of the quadratic equation, as they define the intervals that determine the solution set. Test a value within each interval to determine the regions that satisfy the inequality. Shade the appropriate area on the graph according to whether the inequality holds true within those intervals.
For example, if the inequality is of the form ax2 + bx + c < 0 or ax2 + bx + c > 0, shade the region where the parabola is below or above the x-axis, respectively. If itβs ax2+ bx + c β€ 0 or ax2 + bx + c β₯ 0, include points on the parabola itself.
The graph provides a clear visualization of the solution set of the quadratic inequality, aiding in understanding its solution regions on the coordinate plane.
Also Check
Quadratic Inequalities β Solved Examples
Example 1. Solve the inequality: x2 β 4x + 3 > 0.
Solution:
Given inequality: x2 β 4x + 3 > 0
Step 1: Factorize the quadratic expression:
x2 β 4x + 3 = (x β 3)(x β 1) > 0
Step 2: Find intervals where the expression is positive:
Interval I: x < 1
For x < 1, consider the factors (x β 3)(x β 1):
Pick a test point, say x = 0, substitute into (x β 3)(x β 1):
(0 β 3)(0 β 1) = (-3)(-1) = 3 > 0
The inequality holds for x < 1.
Interval II: 1 < x < 3
For 1 < x < 3, consider the factors (x β 3)(x β 1):
Pick a test point, say x = 2, substitute into (x β 3)(x β 1):
(2 β 3)(2 β 1) = (-1)(1) = -1 < 0
The inequality doesnβt hold for 1 < x < 3.
Interval III: x > 3
For x > 3, consider the factors (x β 3)(x β 1):
Pick a test point, say x = 4, substitute into (x β 3)(x β 1):
(4 β 3)(4 β 1) = (1)(3) = 3 > 0
The inequality holds for x > 3.
Therefore, the solution is x < 1 or x > 3.
Example 2. Solve the inequality: x2 + 2x β 15 β€ 0.
Solution:
Given inequality: x2 + 2x β 15 β€ 0
Step 1: Factorize the quadratic expression:
x2 + 2x β 15 = (x + 5)(x β 3) β€ 0
Step 2: Find intervals where the expression is non-positive:
Interval I: -5 β€ x β€ 3
For -5 β€ x β€ 3, consider the factors (x + 5)(x β 3):
Pick a test point within the interval, say x = 0, substitute into (x + 5)(x β 3):
(0 + 5)(0 β 3) = (5)(-3) = -15 β€ 0
The inequality holds for -5 β€ x β€ 3.
Therefore, the solution is -5 β€ x β€ 3.
Example 3. Solve the inequality: 2x2 β 5x + 2 > 0.
Solution:
Given inequality: 2x2 β 5x + 2 > 0
Step 1: Factorize the quadratic expression:
2x2 β 5x + 2 = (2x β 1)(x β 2) > 0
Step 2: Find intervals where the expression is positive:
Interval I: x < 1/2
For x < 1/2, consider the factors (2x β 1)(x β 2):
Pick a test point within the interval, say x = 0, substitute into (2x β 1)(x β 2):
(2Γ0 β 1)(0 β 2) = (-1)(-2) = 2 > 0
The inequality holds for x < 1/2.
Interval II: x > 2
For x > 2, consider the factors (2x β 1)(x β 2):
Pick a test point within the interval, say x = 3, substitute into (2x β 1)(x β 2):
(2Γ3 β 1)(3 β 2) = (5)(1) = 5 > 0
The inequality holds for x > 2.
Therefore, the solution is x < 1/2 or x > 2.
Example 4. Solve the inequality: 3x2 β 4x β 4 β€ 0.
Solution:
Given inequality: 3x2 β 4x β 4 β€ 0
Step 1: Factorize the quadratic expression:
3x2 β 4x β 4 = (3x + 2)(x β 2) β€ 0
Step 2: Find intervals where the expression is non-positive:
Interval I: -2/3 β€ x β€ 2
For -2/3 β€ x β€ 2, consider the factors (3x + 2)(x β 2):
Pick a test point within the interval, say x = 0, substitute into (3x + 2)(x β 2):
(3Γ0 + 2)(0 β 2) = (2)(-2) = -4 β€ 0
The inequality holds for -2/3 β€ x β€ 2.
Therefore, the solution is -2/3 β€ x β€ 2.
Example 5. Solve the inequality: x2 + 6x + 9 > 0
Solution:
Given inequality: x2 + 6x + 9 > 0
Step 1: Factorize the quadratic expression:
x2 + 6x + 9 = (x + 3)(x + 3) > 0
Step 2: Find intervals where the expression is positive:
Interval I: x > -3
For x > -3, consider the factor (x + 3)^2:
For any value of x greater than -3, (x + 3)^2 will always be greater than zero because it represents a square value.
Therefore, the solution is x > -3.
Quadratic Inequalities β Practice Questions
Q1. Solve the inequality: 2x2 β 7x + 3 < 0
Q2. Solve the inequality: x2 + 4x + 4 β₯ 0
Q3. Solve the inequality: 4x2 β 12x β 3 > 0
Q4. Solve the inequality: 5x2 β 8x + 3 β€ 0
Q5. Solve the inequality: 3x2 + 5x β 2 > 0
Quadratic Inequalities β FAQs
What are Quadratic Inequalities?
Inequalities involving quadratic expressions (ax2 + bx + c) with inequality signs.
How do you Solve Quadratic Inequalities?
Quadratic Inequalities can be solved by factoring, using the quadratic formula, or graphically interpreting solutions.
What is the Significance of Roots in Quadratic Inequalities?
Roots in Quadratic Inequalities identify critical points where the inequality may change direction.
Can Quadratic Inequalities have no Real Solutions?
Yes, if the quadratic expression does not intersect the x-axis.
Why do we Graph Quadratic Inequalities?
Graphing Quadratic Inequalities helps to visualize regions where the inequality holds true on the coordinate plane.
How to determine the Solution Intervals in Quadratic Inequalities?
To determine the the solution interval we first have to solve the equation and then determine the interval as per the inequality symbol
Can a Quadratic Inequality have Infinite Solutions?
Yes, if the inequality holds true for all values in its domain.
How do Quadratic Inequalities relate to Quadratic Equations?
Solutions of quadratic equations can help find intervals in quadratic inequalities.
What is the difference between Quadratic Equation and Quadratic Inequality?
The basic difference between Quadratic Equation and Quadratic Inequality is a quadratic equation uses equal to sign while quadratic inequality uses inequalities signs such as β , <, β€, >, β₯ between right hand and left hand values