Consider the addition 2+3. This is the same as 2 wholes plus 3 wholes.
We can see from the diagram above that 2+3=5. That is, 2 wholes plus 3 wholes equals 5 wholes.
If we wanted to find 3-2 we would take 2 wholes away from 3 wholes and get 1 whole.
The important thing when adding and subtracting is that we are adding and subtracting quantities of the same amount.
Suppose we want to find \dfrac{2}{7}+\dfrac{3}{7}.
So we can conclude that \dfrac{2}{7}+\dfrac{3}{7}=\dfrac{5}{7}, or 2 sevenths plus 3 sevenths equals 5 sevenths.
When the denominators are the same, we are adding quantities of the same amount. So we can add the numerators and keep the same denominator.
Suppose we want to find \dfrac{3}{7}-\dfrac{2}{7}. Using the same circles as above, we can take two sevenths away from three sevenths.
The part that remains is one seventh of the circle. So we can conclude that \dfrac{3}{7}-\dfrac{2}{7}=\dfrac{1}{7}, or 3 sevenths minus 2 sevenths equals 1 seventh.
When the denominators are the same, we are subtracting quantities of the same amount. So we can subtract the numerators and keep the same denominator.
Evaluate \dfrac{2}{6}+\dfrac{2}{6} and simplify your answer.
When two fractions have the same denominator we can add or subtract them by adding or subtracting the numerators over the same denominator.
If the denominators are different then we are not adding quantities of the same amount. Consider \dfrac{2}{9}+\dfrac{3}{4}. These two fractions look like this.
Before we can add these two fractions we rewrite them with the same denominator. Since we can change the denominator by multiplying the numerator and denominator by the same number, we want to first find a common multiple of the two denominators.
The denominators here are 9 and 4, so a common multiple of the denominators is 4\times9=36.
In this case, the denominators, 4 and 9 have no common factors. This means that 36 is the lowest common multiple of the denominators. This is sometimes called the lowest common denominator.
If the denominators were 4 and 6 instead, then we could find a common multiple the same way. That is, 4\times6=24. However, 24 is not the lowest common multiple of 4 and 6, because the lowest common multiple is 12.
In such a case, we could use either number, because they are both multiples.
This gives us two methods for adding fractions with different denominators. We can always find a common multiple by multiplying the two denominators. However, this will also mean that we will need to simplify the fraction resulting from the addition. Which method is better is a matter of preference.
Now we can rewrite the fractions. Multiplying the numerator and denominator of \dfrac{2}{9} gives \dfrac{2\times4}{9\times4}=\dfrac{8}{36}. Multiplying the numerator and denominator of \dfrac{3}{4} gives \dfrac{3\times9}{4\times9}=\dfrac{27}{36}. Now these fractions look like this.
And now that the denominators are the same, we can add the fractions together.
We can see that \dfrac{2}{9}+\dfrac{3}{4}=\dfrac{8}{36}+\dfrac{27}{36}=\dfrac{35}{36}
So when the denominators are different, we rewrite the fractions with the same denominator, and then we can follow the procedure for fractions with the same denominator.
The following applet demonstrates adding fractions with area models.
We can use area models to change fractions to equivalent fractions so the denominators are the same. Then we can add the equivalent fractions.
Suppose we want to find \dfrac{3}{4}-\dfrac{2}{9}. Since the denominators are different, we rewrite the fractions with the same denominator before we subtract them. From the previous example we know that \dfrac{3}{4}=\dfrac{27}{36} and \dfrac{2}{9}=\dfrac{8}{36}.
When we take \dfrac{8}{36} away from \dfrac{27}{36} we are left with \dfrac{19}{36}.\dfrac{3}{4}-\dfrac{2}{9}=\dfrac{27}{36}-\dfrac{8}{36}=\dfrac{19}{36}
So when the denominators are different, we rewrite the fractions with the same denominator, and then we can follow the procedure for fractions with the same denominator.
Evaluate \dfrac{3}{4}-\dfrac{1}{8}.
When two fractions have different denominators we first rewrite the fractions with the same denominator. Then we can add or subtract the numerators over the same denominator.
Mixed numbers have a whole number part and a fraction part. The best way to add or subtract mixed numbers is to convert the mixed numbers into improper fractions. Then we can rewrite the improper fractions with the same denominator and add or subtract the fractions.
For example, to find the value of 2\,\dfrac{3}{4}-1\,\dfrac{5}{6}we can start by rewriting both mixed numbers as improper fractions:
\displaystyle 2\,\dfrac{3}{4} | \displaystyle = | \displaystyle \dfrac{8}{4}+\dfrac{3}{4} | Write the whole part as a fraction |
\displaystyle = | \displaystyle \dfrac{11}{4} | Add the fractions | |
\displaystyle 1\,\dfrac{5}{6} | \displaystyle = | \displaystyle \dfrac{6}{6}+\dfrac{5}{6} | Write the whole part as a fraction |
\displaystyle = | \displaystyle \dfrac{11}{6} | Add the fractions |
Rewriting these improper fractions with the same denominator gives:
\displaystyle \dfrac{11}{4} | \displaystyle = | \displaystyle \dfrac{11\times3}{4\times3} | Multiply the numerator and denominator by 3 |
\displaystyle = | \displaystyle \dfrac{33}{12} | Evaluate | |
\displaystyle \dfrac{11}{6} | \displaystyle = | \displaystyle \dfrac{11\times2}{6\times2} | Multiply the numerator and denominator by 2 |
\displaystyle = | \displaystyle \dfrac{22}{12} | Evaluate |
\displaystyle 2\,\dfrac{3}{4}-1\,\dfrac{5}{6} | \displaystyle = | \displaystyle \dfrac{33}{12}-\dfrac{22}{12} | Subtract the improper fractions |
\displaystyle = | \displaystyle \dfrac{11}{12} | Evaluate |
Evaluate 2\,\dfrac{3}{11} + 4\,\dfrac{7}{11}.
To add or subtract mixed numbers, we first write them as improper fractions and then we can use the same process to add or subtract them.