Quadratic Inequalities
Quadratic Inequalities
A quadratic inequality is an inequality that contains a quadratic expression. The standard forms are ax2+bx+c>0, ax2+bx+c<0, ax2+bx+câ¥0, or ax2+bx+câ€0.
Solving a quadratic inequality means finding all the values of x that make the inequality true. Instead of a single number, the solution is usually a range (or interval) of numbers on the number line.
How to Solve Quadratic Inequalities
To solve a quadratic inequality, follow these three main steps:
- Move everything to one side: Ensure one side of the inequality is zero.
- Find the critical points: Treat the inequality symbol as an equal sign and solve the quadratic equation (usually by factoring) to find the roots. These roots divide the number line into distinct intervals.
- Determine the correct intervals: Use a sign chart to test a number in each interval, or quickly sketch the parabola to see where the graph is above or below the x-axis.
Example 1: Solving with a Sign Chart
Solve: x2â5x+6>0
Step 1: Find the critical points. Set the expression to zero and factor: x2â5x+6=0 (xâ2)(xâ3)=0 The critical points are x=2 and x=3.
Step 2: Set up intervals. These points divide the number line into three intervals:
- x<2
- 2<x<3
- x>3
Step 3: Test each interval. Pick a test value in each interval to see if (xâ2)(xâ3) is positive or negative:
- For x=0 (in x<2): (0â2)(0â3)=(â2)(â3)=6. Positive!
- For x=2.5 (in 2<x<3): (2.5â2)(2.5â3)=(0.5)(â0.5)=â0.25. Negative.
- For x=4 (in x>3): (4â2)(4â3)=(2)(1)=2. Positive!
Since our original inequality is >0 (we want the positive values), the solution is the intervals where the result is positive.
Solution: x<2 or x>3
Example 2: Solving by Sketching the Parabola
Solve: âx2+4xâ3â¥0
Step 1: Make the leading coefficient positive (optional but helpful). Multiply the entire inequality by â1. Remember that multiplying or dividing an inequality by a negative number flips the inequality sign: x2â4x+3â€0
Step 2: Find the critical points. Factor the quadratic: (xâ1)(xâ3)=0 The critical points are x=1 and x=3.
Step 3: Sketch the parabola. Look at the graph of y=x2â4x+3. Since the x2 coefficient is positive (1>0), the parabola opens upwards (like a "U" shape). It crosses the x-axis at x=1 and x=3.
We want to know where the parabola is â€0 (below or touching the x-axis). Looking at our mental "U" shape, the graph dips below the x-axis strictly between the roots 1 and 3.
Solution: 1â€xâ€3