3.03 Solving linear inequalities
Inequalities
When we solve equations, we can apply the same operation to both sides and the equation remains true. Consider the following equation: x+7=12
We can subtract 7 from both sides of the equation in order to find the value of x. This is because both sides of the equation are identical, so what we do to one side, we should do to the other side.
| \displaystyle x+7 | \displaystyle = | \displaystyle 12 | Rewrite the equation |
| \displaystyle x+7-7 | \displaystyle = | \displaystyle 12-7 | Subtract 7 from both sides |
| \displaystyle x | \displaystyle = | \displaystyle 6 | Evaluate |
When working with inequalities, we can follow exactly the same procedure, but with an inequality sign in place of the equals sign. But there are two operations that we need to be careful of.
Consider the inequality 9<15.
If we add or subtract both sides by any number, say 3, we can see that the resulting inequality remains true.
The inequality stays the same and it is true that 12 is less than 18.
Once again the inequality stays the same and it is true that 6 is less than 12.
Adding a negative would have the same effect as subtracting, so we can also add and subtract negative numbers without changing the inequality.
What happens if we multiply or divide both sides?
Let's look at what happens when we multiply by a positive number:
| \displaystyle 9 | \displaystyle < | \displaystyle 15 | Given |
| \displaystyle 9\times3 | \displaystyle < | \displaystyle 15\times3 | Multiply both sides by 3 |
| \displaystyle 27 | \displaystyle < | \displaystyle 45 | Evaluate |
The inequality stays the same, and it is true that 27 is less than 45.
Now let's look at what happens when we divide by a positive number:
| \displaystyle 9 | \displaystyle < | \displaystyle 15 | Given |
| \displaystyle \dfrac{9}{3} | \displaystyle < | \displaystyle \dfrac{15}{3} | Divide both sides by 3 |
| \displaystyle 3 | \displaystyle < | \displaystyle 5 | Evaluate |
The inequality stays the same, and it is true that 3 is less than 5.
But now let's look what happens when we multiply by a negative number:
\begin{aligned} 9& &< &&&15 &&\text{Given} \\ 9 \times \left(-3\right)& &⬚ &&&15 \times \left(-3\right) &&\text{Multiply both sides by} -3 \\ -27& &⬚ &&&-45 &&\text{Evaluate} \end{aligned}
What inequality sign goes in the boxes on lines two and three? Can we just keep the original inequality sign?
If we look at the last line, we can see that -27 is actually greater than -45, as it further to the right on a number line. So we have to reverse the inequality sign whenever we multiply by a negative number. This gives us the following:
| \displaystyle 9 | \displaystyle < | \displaystyle 15 | Given |
| \displaystyle 9\times(-3) | \displaystyle > | \displaystyle 15\times(-3) | Multiply both sides by 3, reverse inequality |
| \displaystyle -27 | \displaystyle > | \displaystyle -45 | Evaluate |
So we can see that -27 is greater than -45.
To divide by a negative we will need to use the same trick:
| \displaystyle 9 | \displaystyle < | \displaystyle 15 | Given |
| \displaystyle \dfrac{9}{-3} | \displaystyle > | \displaystyle \dfrac{15}{-3} | Divide both sides by -3, reverse inequality |
| \displaystyle -3 | \displaystyle > | \displaystyle -5 | Evaluate |
So once again, the inequality switches from < to >.
Now that we have seen what happens when we perform addition, subtraction, multiplication and division, we can use this knowledge to solve inequalities.
Before jumping in algebraically, it can be helpful to consider some possible solutions and non-solutions. Then we can look at an algebraic strategy.
Examples
Example 1
Solve the following inequality: x-10<13
Example 2
Solve the following inequality: \dfrac{x}{-9} \geq 4
The following operations don't change the inequality symbol used:
- Adding a number to both sides of an inequality.
- Subtracting a number from both sides of an inequality.
- Multiplying both sides of an inequality by a positive number.
- Dividing both sides of an inequality by a positive number.
The following operations reverse the inequality symbol used:
- Multiplying both sides of an inequality by a negative number.
- Dividing both sides of an inequality by a negative number.
Real life applications
Much as with solving equations from written descriptions, there are certain key words or phrases to look out for. When it comes to inequalities, we now have a few extra key words and phrases to represent the different inequality symbols.
Phrases that can be used to represent an inequality symbol:
- > greater than, more than
- \geq greater than or equal to, at least, no less than
- < less than
- \leq less than or equal to, at most, no more than
Examples
Example 3
Neville is saving up to buy a plasma TV that is selling for \$950. He has \$650 in his bank account and expects a nice sum of money for his birthday next month.
If the amount he is to receive for his birthday is represented by x, which of the following inequalities models the situation where he is able to afford the TV?
Phrases that can be used to represent an inequality symbol:
- > greater than, more than
- \geq greater than or equal to, at least, no less than
- < less than
- \leq less than or equal to, at most, no more than