Practice with Fractions
Multiplying and Dividing Fractions

To see more practice with fractions, follow the links:

Adding and Subtracting Fractions
Simplifying Fractions

Multiplying and dividing fractions have simple rules. When you multiply 2 fractions, all you have to do is multiply the numerators together and multiply the denominators together. For instance:

$$
{\Large{3 \over 5} \cdot {7 \over {25}} = {{3 \cdot 7} \over {5 \cdot 25}} = {{21} \over {125}}}
$$

In this case, the fraction is already simplified, so we don’t have to go any further.

Dividing is not much more difficult. When you divide 2 fractions, just flip the second fraction and multiply. So, for instance:

$$
{\Large{3 \over 4}} \div {\Large{2 \over 3}} = {\Large{3 \over 4}} \cdot {\Large{3 \over 2}} = {\Large{9 \over 8}}
$$

Again, the fraction is in simplified form, so we are done.

Many of us have memorized these rules, but have you ever wondered why they work? Take a moment to think about them before you read further.

Example 1

First, let’s take multiplication. Why is it that when you multiply fractions, you multiply the numerators and the denominators?

Well, let’s take a look at an example:

$$
{\Large{1 \over 4} \cdot {1 \over 3} = {{1 \cdot 1} \over {4 \cdot 3}} = {1 \over {12}}}
$$

One way to think of multiplication is repeated addition. When dealing with integers, this is easy to see. For instance $$ 7 \cdot 8 $$  means that we have seven 8’s, or 8+8+8+8+8+8+8. We can carry this idea of repeated addition to fractions, too. In this case we have $$ {\Large{1 \over 4} \cdot {1 \over 3}} $$ , or, if we follow the idea above, we have one-third “$$ {\Large{1 \over 4}} $$ ”s. In other words, $$ {\Large{1 \over 3}} $$  of $$ {\Large{1 \over 4}} $$ . When we take $$ {\Large{1 \over 3}} $$  of something, we divide it by 3. To divide $$ {\Large{1 \over 4}} $$  by 3 means to take that part of the whole and make it 3 times smaller. So, when we cut $$ {\Large{1 \over 4}} $$  into 3 pieces, each of those pieces will be $$ {\Large{1 \over {12}}}  of the whole.

Example 2

Now, let’s take a look at dividing fractions. The rule tells us to “invert and multiply” which means to take the reciprocal of the second fraction and multiply the fractions together. This seems like an arbitrary rule, but it’s actually not that strange. Take a division problem involving just integers, for example: $$ 16 \div 4 $$ . Even though we don’t think about it, in a division problem like this, we invert and multiply, too. We could re-write this as $$ 16 \cdot {\Large{1 \over 4}} $$  because we are taking $$ {\Large{1 \over 4}} $$  of 16, which in either case, is 4. Division is really just inverted multiplication. We find $$ {\Large{1 \over 4}} $$ of 16 when we divide by 4 because we are trying to find the number that, when multiplied by 4, will give us 16.

Some practice problems to check your skills:

1. Multiply the fractions and simplify your answer:

            $$
{\Large{3 \over {12}}} \cdot {\Large{7 \over {36}}}
$$

Think about it for a moment and then access this link to view answer.

2. Multiply the fractions and simplify your answer:

            $$
{\Large{{500} \over {1000}}} \cdot {\Large{{36} \over {48}}}
$$

Think about it for a moment and then access this link to view answer.

3. Multiply the fractions and simplify your answer:

            $$
{\Large{7 \over 9}} \cdot {\Large{3 \over 2}} \cdot {\Large{{81} \over {49}}}
$$

Think about it for a moment and then access this link to view answer.

4. Divide the fractions and simplify your answer:

            $$
{\Large{{34} \over {56}}} \div {\Large{{17} \over 8}}
$$

Think about it for a moment and then access this link to view answer.

5. Multiply and divide, and then simplify your answer:

            $$
{\Large{5 \over 7}} \div {\Large{9 \over {84}}} \cdot {\Large{7 \over {42}}}
$$

Think about it for a moment and then access this link to view answer.