4.3 Linear Absolute Value Inequalities

Absolute values are positive magnitudes, which means that they represent the positive value of any number.

For instance, | −5 | and | +5 | are the same, with both having the same value of 5, and | −99 | and | +99 | both share the same value of 99.

When used in inequalities, absolute values become a boundary limit to a number.

Example 4.3.1

Consider [latex]| x | < 4.[/latex] This means that the unknown [latex]x[/latex] value is less than 4, so [latex]| x | < 4[/latex] becomes [latex]x < 4.[/latex] However, there is more to this with regards to negative values for [latex]x.[/latex] | −1 | is a value that is a solution, since 1 <  4. However, | −5 | < 4 is not a solution, since 5  >  4. The boundary of [latex]| x | < 4[/latex] works out to be between −4 and +4. This means that [latex]| x | < 4[/latex] ends up being bounded as [latex]-4 <  x  < 4.[/latex] If the inequality is written as [latex]| x | \le 4[/latex], then little changes, except that [latex]x[/latex] can then equal −4 and +4, rather than having to be larger or smaller. This means that [latex]| x | \le 4[/latex] ends up being bounded as [latex]-4 \le  x  \le 4.[/latex]

Example 4.3.2

Consider [latex]|x| > 4.[/latex]

This means that the unknown [latex]x[/latex] value is greater than 4, so [latex]|x| > 4[/latex] becomes [latex]x > 4.[/latex] However, the negative values for [latex]x[/latex] must still be considered.

The boundary of [latex]|x| > 4[/latex] works out to be smaller than −4 and larger than +4.

This means that [latex]|x| > 4[/latex] ends up being bounded as [latex]x < -4  \text{ or }  4 < x.[/latex] If the inequality is written as [latex]| x | \ge 4,[/latex] then little changes, except that [latex]x[/latex] can then equal −4 and +4, rather than having to be larger or smaller. This means that [latex]|x| \ge 4[/latex] ends up being bounded as  [latex]x \le -4  \text{ or }  4 \le x.[/latex]

When drawing the boundaries for inequalities on a number line graph, use the following conventions:

For ≤ or ≥, use [brackets] as boundary limits.Blank number line with square brackets positioned on it.

For < or >, use (parentheses) as boundary limits. Blank number line with parentheses positioned on it.

Equation Number Line
[latex]| x | <4[/latex] x < 4. Left parenthesis on −4; right parenthesis on 4.
[latex]| x | \le 4[/latex] x ≤ 4. Left square bracket on −4; right bracket on 4.
[latex]| x | > 4[/latex] image 4. Right parenthesis on −4; left parenthesis on 4. Arrows to both infinities.” class=”alignnone wp-image-136″ width=”336″ height=”56″>
[latex]| x | \ge 4[/latex] x ≥ 4. Right square bracket on −4; left bracket on 4. Arrows to both infinities.

When an inequality has an absolute value, isolate the absolute value first in order to graph a solution and/or write it in interval notation. The following examples will illustrate isolating and solving an inequality with an absolute value.

Example 4.3.3

Solve, graph, and give interval notation for the inequality  [latex]-4  - 3 | x | \ge  -16.[/latex]

First, isolate the inequality:

\[\begin{array}{rrrrrl}
-4&-&3|x|& \ge & -16 &\\
+4&&&&+4& \text{add 4 to both sides}\\
\hline
&&\dfrac{-3|x|}{-3}& \ge & \dfrac{-12}{-3}&\text{divide by }-3 \text{ and flip the sense} \\ \\
&&|x|&\le & 4 &&
\end{array}\]

At this point, it is known that the inequality is bounded by 4. Specifically, it is between −4 and 4.

This means that [latex]-4 \le | x | \le 4.[/latex]

This solution on a number line looks like:

−4 ≤ | x | ≤ 4. Left square bracket at −4; right bracket at 4.

To write the solution in interval notation, use the symbols and numbers on the number line: [latex][-4, 4].[/latex]

Other examples of absolute value inequalities result in an algebraic expression that is bounded by an inequality.

Example 4.3.4

Solve, graph, and give interval notation for the inequality [latex]| 2x - 4 | \le  6.[/latex]

This means that the inequality to solve is [latex]-6\le 2x - 4\le 6[/latex]:

[latex]\begin{array}{rrrcrrr} -6&\le & 2x&-&4&\le & 6 \\ +4&&&+&4&&+4 \\ \hline \dfrac{-2}{2}&\le &&\dfrac{2x}{2}&&\le & \dfrac{10}{2} \\ \\ -1 &\le &&x&&\le & 5 \end{array}[/latex]

−1 ≤ x ≤ 5. Left square bracket on −1; right bracket on 5.

To write the solution in interval notation, use the symbols and numbers on the number line: [latex][-1,5].[/latex]

Example 4.3.5

Solve, graph, and give interval notation for the inequality [latex]9  -  2 | 4x + 1 |  > 3.[/latex]

First, isolate the inequality by subtracting 9 from both sides:

\[\begin{array}{rrrrrrr}
9&-&2|4x&+&1|&>&3 \\
-9&&&&&&-9 \\
\hline
&&-2|4x&+&1|&>&-6 \\
\end{array}\]

Divide both sides by −2 and flip the sense:

\[\begin{array}{rrr}
\dfrac{-2|4x+1|}{-2}&>&\dfrac{-6}{-2} \\ \\
|4x+1|&<& 3
\end{array}\]

At this point, it is known that the inequality expression is between −3 and 3, so [latex]-3  <  4x + 1  <  3.[/latex] All that is left is to isolate [latex]x[/latex]. First, subtract 1 from all three parts: \[\begin{array}{rrrrrrr} -3&<&4x&+&1&<&3 \\ -1&&&-&1&&-1 \\ \hline -4&<&&4x&&<&2 \\ \end{array}\] Then, divide all three parts by 4: \[\begin{array}{rrrrr} \dfrac{-4}{4}&<&\dfrac{4x}{4}&<&\dfrac{2}{4} \\ \\ -1&<&x&<&\dfrac{1}{2} \\ \end{array}\] −1 < x < ½. Left parenthesis on −1; right parenthesis on ½.

In interval notation, this is written as [latex]\left(-1,\dfrac{1}{2}\right).[/latex]

It is important to remember when solving these equations that the absolute value is always positive. If given an absolute value that is less than a negative number, there will be no solution because absolute value will always be positive, i.e., greater than a negative. Similarly, if absolute value is greater than a negative, the answer will be all real numbers.

This means that:

[latex]\begin{array}{c} | 2x - 4 | <  -6 \text{ has no possible solution } (x \ne \mathbb{R}) \\ \\ \text{and} \\ \\ | 2x - 4 | >  -6 \text{ has every number as a solution and is written as } (-\infty, \infty) \end{array}[/latex]

Note: since infinity can never be reached, use parentheses instead of brackets when writing infinity (positive or negative) in interval notation.

Questions

For questions 1 to 33, solve each inequality, graph its solution, and give interval notation.

  1. [latex]| x | < 3[/latex]
  2. [latex]| x | \le 8[/latex]
  3. [latex]| 2x | < 6[/latex]
  4. [latex]| x + 3 | < 4[/latex]
  5. [latex]| x - 2 | < 6[/latex]
  6. [latex]| x - 8 | < 12[/latex]
  7. [latex]| x - 7 | < 3[/latex]
  8. [latex]| x + 3 | \le 4[/latex]
  9. [latex]| 3x - 2 | < 9[/latex]
  10. [latex]| 2x + 5 | < 9[/latex]
  11. [latex]1 + 2 | x - 1 | \le 9[/latex]
  12. [latex]10 - 3 | x - 2 | \ge 4[/latex]
  13. [latex]6 -  | 2x - 5 |  > 3[/latex]
  14. [latex]| x | > 5[/latex]
  15. [latex]| 3x |  > 5[/latex]
  16. [latex]| x - 4 | > 5[/latex]
  17. [latex]| x + 3 | > 3[/latex]
  18. [latex]| 2x - 4 | > 6[/latex]
  19. [latex]| x - 5 | > 3[/latex]
  20. [latex]3 -  | 2 - x | < 1[/latex]
  21. [latex]4 + 3 | x - 1 |  < 10[/latex]
  22. [latex]3 - 2 | 3x - 1 | \ge -7[/latex]
  23. [latex]3 - 2 | x - 5 | \le -15[/latex]
  24. [latex]4 - 6 | -6 - 3x | \le -5[/latex]
  25. [latex]-2 - 3 | 4 - 2x | \ge -8[/latex]
  26. [latex]-3 - 2 | 4x - 5 | \ge 1[/latex]
  27. [latex]4 - 5 | -2x - 7 | < -1[/latex]
  28. [latex]-2 + 3 | 5 - x | \le 4[/latex]
  29. [latex]3 - 2 | 4x - 5 | \ge 1[/latex]
  30. [latex]-2 - 3 | - 3x - 5| \ge  -5[/latex]
  31. [latex]-5 - 2 | 3x - 6 | < -8[/latex]
  32. [latex]6 - 3 | 1 - 4x | < -3[/latex]
  33. [latex]4 - 4 | -2x + 6 | > -4[/latex]

Answer Key 4.3

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