We have now looked at solving inequalities that involve one or two steps to solve. We're now going to take a look at how we can use inequalities to solve problems given a written description.

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

$>$>- greater than, more than.

$\ge$≥- greater than or equal to, at least, no less than.

$<$<- less than.

$\le$≤- less than or equal to, at most, no more than.

Worked example

Question 1

Construct and solve an inequality for the following situation:

"The sum of $2$2 lots of $x$x and $1$1 is at least $7$7."

Think: "At least" means the same as "greater than or equal to". Also "lots of" means there is a multiplication, and "sum" means there is an addition.

Do: $2$2 lots of $x$x is $2x$2x, and the sum of this and $1$1 is $2x+1$2x+1. So altogether we have that "the sum of $2$2 lots of $x$x and $1$1 is at least $7$7" can be written as $2x+1\ge7$2x+1≥7.

We can now solve the inequality for $x$x:

$2x+1$2x+1

$\ge$≥

$7$7

$2x$2x

$\ge$≥

$6$6

$x$x

$\ge$≥

$3$3

So the possible values of $x$x are those that are greater than or equal to $3$3.

Practice questions

Question 1

Consider the following situation:

"$2$2 less than $4$4 groups of $p$p is no more than $18$18".

Construct and solve the inequality described above.

What is the largest value of $p$p that satisfies this condition?

$p=5$p=5

A

$p=-5$p=−5

B

There is no largest value.

C

$p=4$p=4

D

Question 2

Lachlan is planning on going on vacation. He has saved $£2118.40$£2118.40, and spends $£488.30$£488.30 on his airplane ticket.

Let $x$x represent the amount of money Lachlan spends on the rest of his holiday.

Write an inequality to represent the situation, and then solve for $x$x.

What is the most that Lachlan could spend on the rest of his holiday?

Question 3

At a sports clubhouse the coach wants to rope off a rectangular area that is adjacent to the building. He uses the length of the building as one side of the area, which measures $26$26 meters. He has at most $42$42 meters of rope available to use.

If the width of the roped area is $W$W, form an inequality and solve for the range of possible widths.