Absolute Value Equations & Inequalities
Eleventh Grade Mathematics - Complete Notes & Formulae
What is Absolute Value?
The absolute value of a number is its distance from zero on the number line, regardless of direction. It is always non-negative.
\( |x| = \begin{cases} x & \text{if } x \geq 0 \\ -x & \text{if } x < 0 \end{cases} \)
Examples: \( |5| = 5 \), \( |-5| = 5 \), \( |0| = 0 \)
Key Properties of Absolute Value:
- \( |a| \geq 0 \) for all real numbers a (always non-negative)
- \( |a| = |-a| \) (symmetry property)
- \( |ab| = |a| \cdot |b| \) (product property)
- \( |\frac{a}{b}| = \frac{|a|}{|b|} \) where \( b \neq 0 \) (quotient property)
- \( |a|^2 = a^2 \) (square property)
1. Solve Absolute Value Equations
General Form:
\( |ax + b| = c \)
Steps to Solve Absolute Value Equations:
- Step 1: Isolate the absolute value expression
- Get \( |ax + b| \) by itself on one side
- Step 2: Check the value on the other side
- If c < 0: No solution (absolute value cannot be negative)
- If c = 0: One solution (set expression = 0)
- If c > 0: Two solutions (continue to Step 3)
- Step 3: Write two equations (positive and negative cases)
- \( ax + b = c \) AND \( ax + b = -c \)
- Step 4: Solve both equations
- Find x for each equation
- Check both solutions in the original equation
Solution Formula:
If \( |X| = p \) where \( p > 0 \), then \( X = p \) OR \( X = -p \)
Example 1: Simple Equation
Solve: \( |x - 3| = 7 \)
Step 1: Already isolated
Step 2: c = 7 > 0, so two solutions exist
Step 3: Write two equations:
• \( x - 3 = 7 \)
• \( x - 3 = -7 \)
Step 4: Solve both:
• \( x = 10 \)
• \( x = -4 \)
Solution: \( x = 10 \) or \( x = -4 \)
Example 2: Equation Requiring Isolation
Solve: \( 2|3x + 1| - 5 = 9 \)
Step 1: Isolate absolute value:
\( 2|3x + 1| = 14 \)
\( |3x + 1| = 7 \)
Step 3: Write two equations:
• \( 3x + 1 = 7 \) → \( 3x = 6 \) → \( x = 2 \)
• \( 3x + 1 = -7 \) → \( 3x = -8 \) → \( x = -\frac{8}{3} \)
Solution: \( x = 2 \) or \( x = -\frac{8}{3} \)
Example 3: No Solution
Solve: \( |2x - 5| + 3 = 1 \)
Step 1: Isolate: \( |2x - 5| = -2 \)
Step 2: Since -2 < 0, absolute value cannot equal a negative number
Solution: No solution (∅)
2. Graph Solutions to Absolute Value Equations
Graphing on a Number Line:
Solutions to absolute value equations are represented as points on the number line.
- Solid dots (•) represent the solutions
- For \( |x| = c \), plot points at \( x = c \) and \( x = -c \)
- No solution: No points on number line
Steps to Graph Solutions:
- Solve the absolute value equation
- Draw a number line with appropriate scale
- Mark each solution with a solid dot
- Label the points with their values
Example: Graph \( |x - 2| = 5 \)
Solve:
• \( x - 2 = 5 \) → \( x = 7 \)
• \( x - 2 = -5 \) → \( x = -3 \)
Graph: Place solid dots at x = -3 and x = 7 on the number line
←———•—————————•———→
-3 7
3. Write Absolute Value Equations from Graphs
Steps to Write Equations from Graphs:
- Step 1: Identify the solutions from the graph
- Find the marked points on the number line
- Let these be \( x_1 \) and \( x_2 \)
- Step 2: Find the midpoint (center)
- Midpoint \( h = \frac{x_1 + x_2}{2} \)
- Step 3: Find the distance from center
- Distance \( d = \frac{|x_2 - x_1|}{2} \) or \( d = |x_1 - h| \)
- Step 4: Write the equation
- \( |x - h| = d \)
Quick Formula:
If solutions are \( x_1 \) and \( x_2 \), then: \( |x - \frac{x_1+x_2}{2}| = \frac{|x_2-x_1|}{2} \)
Example 1: Write Equation from Graph
Given: Points at x = 2 and x = 8
Step 1: \( x_1 = 2 \), \( x_2 = 8 \)
Step 2: Midpoint: \( h = \frac{2 + 8}{2} = 5 \)
Step 3: Distance: \( d = \frac{|8 - 2|}{2} = 3 \)
Equation: \( |x - 5| = 3 \)
Example 2: Negative Solutions
Given: Points at x = -6 and x = 4
Step 2: Midpoint: \( h = \frac{-6 + 4}{2} = -1 \)
Step 3: Distance: \( d = \frac{|4 - (-6)|}{2} = 5 \)
Equation: \( |x + 1| = 5 \) (same as \( |x - (-1)| = 5 \))
4. Solve Absolute Value Inequalities
Two Types of Absolute Value Inequalities:
| Type | Form | Solution | Type |
|---|---|---|---|
| Less Than | \( |X| < c \) or \( |X| \leq c \) | \( -c < X < c \) | AND (Conjunction) |
| Greater Than | \( |X| > c \) or \( |X| \geq c \) | \( X < -c \) OR \( X > c \) | OR (Disjunction) |
Key Formulas:
Less Than Type (AND - Bounded):
If \( |X| < c \) where \( c > 0 \), then \( -c < X < c \)
Interval notation: \( (-c, c) \)
Greater Than Type (OR - Unbounded):
If \( |X| > c \) where \( c > 0 \), then \( X < -c \) OR \( X > c \)
Interval notation: \( (-\infty, -c) \cup (c, \infty) \)
Steps to Solve Absolute Value Inequalities:
- Step 1: Isolate the absolute value
- Step 2: Identify the type
- Less than (< or ≤) → AND compound inequality
- Greater than (> or ≥) → OR compound inequality
- Step 3: Rewrite without absolute value
- For |X| < c: write \( -c < X < c \)
- For |X| > c: write \( X < -c \) OR \( X > c \)
- Step 4: Solve and write solution
- Solve the resulting inequality/inequalities
- Express in interval notation
Example 1: Less Than (AND)
Solve: \( |x - 3| < 5 \)
Step 1: Already isolated
Step 2: Less than type → AND
Step 3: Rewrite: \( -5 < x - 3 < 5 \)
Step 4: Add 3 to all parts: \( -2 < x < 8 \)
Solution: \( (-2, 8) \) or \( -2 < x < 8 \)
Example 2: Greater Than (OR)
Solve: \( |2x + 1| \geq 7 \)
Step 2: Greater than or equal type → OR
Step 3: Rewrite: \( 2x + 1 \leq -7 \) OR \( 2x + 1 \geq 7 \)
Step 4: Solve each:
• \( 2x \leq -8 \) → \( x \leq -4 \)
• \( 2x \geq 6 \) → \( x \geq 3 \)
Solution: \( (-\infty, -4] \cup [3, \infty) \) or \( x \leq -4 \) or \( x \geq 3 \)
Example 3: With Isolation
Solve: \( 3|x - 2| + 5 > 14 \)
Step 1: Isolate: \( 3|x - 2| > 9 \) → \( |x - 2| > 3 \)
Step 3: \( x - 2 < -3 \) OR \( x - 2 > 3 \)
Step 4: \( x < -1 \) OR \( x > 5 \)
Solution: \( (-\infty, -1) \cup (5, \infty) \)
5. Graph Solutions to Absolute Value Inequalities
Graphing on a Number Line:
Solutions to inequalities are shown as intervals (shaded regions) on the number line.
| Symbol | Endpoint |
|---|---|
| < or > | Open circle (○) - not included |
| ≤ or ≥ | Closed circle (•) - included |
Steps to Graph:
- Solve the absolute value inequality
- Draw a number line with appropriate scale
- Mark boundary points with circles (open or closed)
- Shade the solution region(s)
- For OR: shade both regions; For AND: shade middle region
Example 1: Less Than (AND) - Single Interval
Graph: \( |x + 1| \leq 4 \) which gives \( -5 \leq x \leq 3 \)
Solution: \( [-5, 3] \)
←———•═══════•———→
-5 3
(Closed circles, shade between)
Example 2: Greater Than (OR) - Two Intervals
Graph: \( |x - 2| > 3 \) which gives \( x < -1 \) or \( x > 5 \)
Solution: \( (-\infty, -1) \cup (5, \infty) \)
←═══○———————○═══→
-1 5
(Open circles, shade both ends)
Graphing Tips:
- AND inequalities: Shade the region BETWEEN the two values (one continuous segment)
- OR inequalities: Shade BOTH regions on the outside (two separate segments)
- Remember: < or > use open circles (○); ≤ or ≥ use closed circles (•)
Quick Reference Summary
Key Concepts:
- Absolute Value Equations: If \( |X| = c \) (c > 0), then \( X = c \) OR \( X = -c \)
- Graph Equations: Mark solutions as solid dots on number line
- Write from Graph: Find midpoint h and distance d, write \( |x - h| = d \)
- Less Than Inequalities: \( |X| < c \) → \( -c < X < c \) (AND, one interval)
- Greater Than Inequalities: \( |X| > c \) → \( X < -c \) OR \( X > c \) (OR, two intervals)
- Graph Inequalities: Shade intervals with open (○) or closed (•) circles
Essential Formulas:
Absolute Value Definition:
\( |x| = \begin{cases} x & \text{if } x \geq 0 \\ -x & \text{if } x < 0 \end{cases} \)
Absolute Value Equation:
If \( |X| = c \) where \( c > 0 \), then \( X = c \) OR \( X = -c \)
Less Than Inequality (AND):
If \( |X| < c \) where \( c > 0 \), then \( -c < X < c \)
Greater Than Inequality (OR):
If \( |X| > c \) where \( c > 0 \), then \( X < -c \) OR \( X > c \)
Special Cases to Remember:
| Case | Solution |
|---|---|
| \( |X| = 0 \) | One solution: \( X = 0 \) |
| \( |X| = \text{negative} \) | No solution (∅) |
| \( |X| < 0 \) | No solution (∅) |
| \( |X| \leq 0 \) | One solution: \( X = 0 \) |
| \( |X| > 0 \) | All real numbers except 0 |
| \( |X| \geq 0 \) | All real numbers (\( \mathbb{R} \)) |
💡 Important Tips & Common Mistakes:
- Always isolate first: Get the absolute value expression alone before splitting
- Check for negative: If absolute value equals a negative, NO solution exists
- AND vs OR: Less than (< or ≤) uses AND (one interval); Greater than (> or ≥) uses OR (two intervals)
- Don't forget negative: When solving equations, always write both \( X = c \) AND \( X = -c \)
- Circle types: Open circles for < or >; Closed circles for ≤ or ≥
- Verify solutions: Always check answers in the original equation
Absolute value equations and inequalities are essential for understanding distance, intervals, and real-world constraints!