4. Algebra

Lesson

So far we have learned about equations, where both sides have the same value. But there will be times when we want to compare two quantities where one is smaller or larger than the other?

An* *inequality exists when one amount is not equal to the other. That is when one side of the expression is greater than the other. We can think of this as a set of unbalanced scales, where one side is heavier than the other.

In mathematics, we have special symbols to indicate that inequality exists. Let's run through them now.

The greater than symbol $>$> indicates that the expression on the left of the symbol has a larger value than the expression on the right of the symbol. For example, $3>2$3>2 means "$3$3 is greater than $2$2".

Similarly, the less than symbol $<$< indicates that the expression on the left of the symbol has a smaller value than the expression on the right of the symbol. For example, $3<4$3<4 means "$3$3 is less than $4$4".

The greater than or equal to symbol $\ge$≥ indicates that the expression on the left of the symbol has a larger value than **or is equal to** the expression on the right of the symbol. So we could write $3\ge2$3≥2, as well as $2\ge2$2≥2, or $n\ge2$`n`≥2. This last expression "$x$`x` is greater than or equal to $2$2" is true for a whole range of values of $n$`n`, such as $n=2$`n`=2, $n=2.5$`n`=2.5 and $n=11$`n`=11.

Similarly, the less than or equal to symbol $\le$≤ indicates that the expression on the left of the symbol has a smaller value than **or is equal to** the expression on the right of the symbol. So we could write $3\le4$3≤4, as well as $4\le4$4≤4, or $x\le4$`x`≤4. Once again, the last expression "$x$`x` is less than or equal to $4$4" is true for a whole range of values of $x$`x`, such as $x=4$`x`=4, $x=3.5$`x`=3.5 and $x=-1$`x`=−1.

Remember

The smaller side of the inequality symbol matches the side with the smaller number. That is, the inequality symbol "points to" the smaller number.

The images below show another demonstration of the inequality symbols:

**Solve:** Write a mathematical statement to mean "two is greater than one".

**Think:** The words "greater than" refer to the symbol $>$>.

**Do:** We can write this statement as $2>1$2>1.

**Solve:** Write a mathematical statement to mean "$k$`k` is less than or equal to seven".

**Think:** The words "less than or equal to" refer to the symbol $\le$≤.

**Do:** We can write this statement as $k\le7$`k`≤7.

**Reflect:** There are a whole range of values of $k$`k` which make this inequality true, including $k=7$`k`=7, $k=6.998$`k`=6.998, $k=0$`k`=0 and $k=-15.5$`k`=−15.5.

We are familiar with being able to write an equation in two orders. For example, $x=10$`x`=10 and $10=x$10=`x` mean the same thing.

We can also write inequality statements in two orders, but we now need to be careful and switch the inequality sign being used as well.

For example, $x>10$`x`>10 means the same thing as $10`x`. That is, "$x$`x` is greater than ten" is the same as "ten is less than $x$`x`".

Write the following sentence using mathematical symbols:

$n$`n` is greater than $9$9.

Choose the mathematical symbol that makes this number sentence true.

$\frac{2}{3}$23$\editable{}$$0.3$0.3

$<$<

A$>$>

B$=$=

C$<$<

A$>$>

B$=$=

C

If $x>15$`x`>15, what is the smallest integer value $x$`x` can have?

Smallest integer value$=$=$\editable{}$

Represent a practical situation with a linear inequality in one variable