Inequalities with Absolute Value
By the end of this lesson, you’ll be able to:
- Solve absolute value inequalities of the form \(|x| < a\), \(|x| > a\), and their shifted/scaled versions.
- Interpret solutions using number-line reasoning.
- Express solutions using interval notation or compound inequalities.
- Solve absolute value inequalities in real-world contexts.
Key Ideas
Absolute value measures distance from zero on the number line.
General forms:
Less than:
\[ |x| < a \quad \Longrightarrow \quad -a < x < a \]Less than or equal:
\[ |x| \le a \quad \Longrightarrow \quad -a \le x \le a \]Greater than:
\[ |x| > a \quad \Longrightarrow \quad x < -a \ \text{ or }\ x > a \]Greater than or equal:
\[ |x| \ge a \quad \Longrightarrow \quad x \le -a \ \text{ or }\ x \ge a \]
For expressions like \(|x - h|\):
- \(|x - h|\) measures distance from \(h\).
- Inequalities describe intervals around or beyond \(h\).
Common Problem Types
Basic Less-Than Inequalities
Translate \(|x|<a\) into a double inequality.
Example:
\(|x| < 3 \Rightarrow -3 < x < 3\).
Basic Greater-Than Inequalities
“Greater than” becomes an OR compound inequality.
Example:
\(|x| > 5 \Rightarrow x < -5\) or \(x > 5\).
Shifted Absolute Value
\(|x - h|\) means distance from \(h\).
Example:
\(|x - 4| < 2 \Rightarrow 2 < x < 6\).
Scaled Absolute Value
First isolate the absolute value.
Example:
\(3|x + 1| \le 9 \Rightarrow |x + 1| \le 3\).
Real-World Context
Absolute value describes a tolerance or maximum deviation.
Example:
A machine allows a temperature within \(2^\circ\) of \(70^\circ\):
\[
|T - 70| \le 2
\]
Strategies
- Always isolate the absolute value before solving.
- Use distance interpretation: “within” → less than; “outside” → greater than.
- Write compound inequalities clearly.
- Check endpoints for strict vs. non-strict inequalities.
- If needed, sketch a quick number line.
Worked Examples
Example 1 — Less Than
Solve: \[ |x| < 4 \]
Translate: \[ -4 < x < 4 \]
Example 2 — Greater Than with Shift
Solve: \[ |x - 3| > 5 \]
Interpret as distance > 5 from 3: \[ x < -2 \quad \text{or} \quad x > 8 \]
Example 3 — Isolate and Solve
Solve: \[ 2|x + 4| \le 10 \]
Divide both sides: \[ |x + 4| \le 5 \]
Translate: \[ -5 \le x + 4 \le 5 \]
Subtract 4: \[ -9 \le x \le 1 \]
Example 4 — Real-World Tolerance
A part must be within \(0.1\) units of length \(5\).
Model: \[ |L - 5| \le 0.1 \]
Thus: \[ 4.9 \le L \le 5.1 \]
- Forgetting to isolate the absolute value before solving.
- Mixing up when to use AND vs. OR.
- Reversing inequalities incorrectly when moving terms.
- Dropping negative signs when translating to compound inequality form.
- Confusing strict (\(<\)) and non-strict (\(\le\)) boundaries.
Practice Problems
Solve:
\[ |x| \le 6 \]Solve:
\[ |x - 2| > 3 \]Solve:
\[ 4|x + 5| < 12 \]A measurement \(M\) must be within \(3\) units of \(20\). Write the inequality and solution interval.
1.
\[
-6 \le x \le 6
\]
2.
\[
x < -1 \quad \text{or} \quad x > 5
\]
3.
Divide: \(|x + 5| < 3\)
Translate: \[
-3 < x + 5 < 3
\] Subtract 5: \[
-8 < x < -2
\]
4.
Model: \(|M - 20| \le 3\)
Interval: \[
17 \le M \le 23
\]
Summary
- “Less than” absolute value → compound AND inequality.
- “Greater than” absolute value → compound OR inequality.
- Always isolate \(| \cdot |\) first.
- Use number-line interpretation to double-check solutions.
- Within = \(|x - h| < a\).
- At least/at most = check inequality sign carefully.
- For greater-than inequalities, split into two cases.
- Draw a number line to visualize intervals.