2.11 Extension: Absolute value inequalities
Inequalities of the form $\left|x\right|
To say $x\le4$x≤4 is to say that $x$x can be any number positive or negative that is not greater than four.
On a number line we draw $x\le4$x≤4 as such:
If the notation is changed slightly to $|x|\le4$|x|≤4, then we are restricting $x$x to be any number between $-4$−4 and $4$4, inclusive.
On a number line we draw $|x|\le4$|x|≤4 as such:
You could check that if $x$x is a number less than $-4$−4, then the absolute value of the number is greater than $4$4. It follows that a statement like $|x|\le4$|x|≤4 is equivalent to a pair of inequalities that can be written $-4\le x\le4$−4≤x≤4.
See the different representations below:
| Absolute Value | Inequality | Interval Notation | Number Line |
|---|---|---|---|
| $\left|x\right|\le4$|x|≤4 | $-4\le x\le4$−4≤x≤4 | $\left[-4,4\right]$[−4,4] | |
| $\left|x\right|<2$|x|<2 | $-2 |
$\left(-2,2\right)$(−2,2) |  |
Inequalities of the form $\left|x\right|>b$|x|>b or $\left|x\right|\ge b$|x|≥b
To solve an inequality (sometimes called an inequation) means to find out the range or ranges of values of the variable for which the statement is true.
Above we looked at $|x|\le4$|x|≤4, and said this was the same as restricting $x$x to be any number between $-4$−4 and $4$4, inclusive.
What about something like $\left|x\right|\ge2$|x|≥2? Well, any number greater than or equal to $2$2 will satisfy this equation, but also any values less than or equal to $-2$−2. This means that this single expression is represented by two disjoint intervals as show below.
See the different representations below:
| Absolute Value | Inequality | Interval Notation | Number Line |
|---|---|---|---|
| $\left|x\right|\ge2$|x|≥2 | $x\le-2$x≤−2 or $x\ge2$x≥2 | $\left(-\infty,-2\right]\cup\left[2,\infty\right)$(−∞,−2]∪[2,∞) | |
| $\left|x\right|>2$|x|>2 | $x<-2$x<−2 or $x>2$x>2 | $\left(-\infty,-2\right)\cup\left(2,\infty\right)$(−∞,−2)∪(2,∞) |  |
Worked examples
Question 1
Solve $\left|x+2\right|>5$|x+2|>5.
Think: It is common practice to consider what happens to the statement in $2$2 parts. The positive side and the negative side.
Do:
Positive side means to consider and solve $+(x+2)>5$+(x+2)>5
| $+(x+2)$+(x+2) | $>$> | $5$5 | (original positive inequality) |
| $x+2$x+2 | $>$> | $5$5 | (remove unnecessary parentheses) |
| $x$x | $>$> | $3$3 | (subtract $2$2 from both sides) |
Negative side means to consider and solve $-(x+2)>5$−(x+2)>5
| $-(x+2)$−(x+2) | $>$> | $5$5 | (original positive inequality) |
| $x+2$x+2 | $<$< | $-5$−5 | (divide both sides by $-1$−1, remember this flips the sign) |
| $x$x | $<$< | $-7$−7 | (subtract $2$2 from both sides) |
This means that for values of $x$x, that are either greater then $3$3 or less than $-7$−7, then the inequality $|x+2|>5$|x+2|>5 will hold true.
This graph shows the solution set. Spot check values inside or outside the range to check.
Alternative approach for Question 1
Another way to think about the previous example is via translations.
Consider first the solution on a number line for $|x|>5$|x|>5. We would know that this means all values of $x$x on the line that are a distance of greater than $5$5 from zero. It would look like this.
The effect of the $+2$+2, is a horizontal translation of $2$2 units to the left. Resulting in our final solution:
Practice questions
Question 2
Rewrite the inequality $\left|x\right|<2$|x|<2 without using absolute values.
Question 3
Rewrite the inequality $\left|x\right|\ge5$|x|≥5 without using absolute values.
Question 4
Solve $\left|4x-8\right|+1=13$|4x−8|+1=13.
Write both solutions as equations on the same line separated by a comma.