13.01 Factorising binomial products (Extended)
We saw how to use the distributive law to expand binomial products. We can also use it to factorise binomial products. In order to find what the factors are, we factorise the terms in pairs.
Worked examples
Example 1
Factorise $xy+8x-3y-24$xy+8x−3y−24
Think: We can use the rule $\left(A+B\right)\left(C+D\right)=AC+AD+BC+BD$(A+B)(C+D)=AC+AD+BC+BD. First we will factorise $xy+8x$xy+8x and $-3y-24$−3y−24 separately. Then we can factorise the whole expression.
Do:
| $xy+8x-3y-24$xy+8x−3y−24 | $=$= | $x\left(y+8\right)-3\left(y+8\right)$x(y+8)−3(y+8) |
Factorising $x$x from $xy+8x$xy+8x and $3$3 from $-3y-24$−3y−24 |
| $=$= | $\left(x-3\right)\left(y+8\right)$(x−3)(y+8) |
Since $\left(y+8\right)$(y+8) is a factor of both terms we can factorise it |
Reflect: We can check that this is the answer by expanding it. Note that sometimes we have to change the order of the terms in order to factorise them this way. For example, if we rearranged the terms to be $xy-3y+8x-24$xy−3y+8x−24 we would get the same answer.
We can also use the special cases of expansion that we learned previously to factorise.
Example 2
Factorise $x^2-6x+9$x2−6x+9
Think: Notice that $-6x=2\times\left(-3x\right)$−6x=2×(−3x). Therefore, $x^2-6x+9$x2−6x+9 is the result of expanding a perfect square.
Do: Using the rule $\left(A+B\right)^2=A^2+2AB+B^2$(A+B)2=A2+2AB+B2, we can see that $A=x$A=x and $B=-3$B=−3. Therefore,
$x^2-6x+9=\left(x-3\right)^2$x2−6x+9=(x−3)2
Reflect: Once again, we can check the answer by expanding it. It's always worth checking if an expression fits the pattern $A^2+2AB+B^2$A2+2AB+B2, because then we can use this special rule. . We call this perfect square factorisation.
Example 3
Factorise $x^2-9$x2−9
Think: Notice that $9=3^2$9=32. Therefore, $x^2-9$x2−9 is the difference of two squares.
Do: Using the rule $\left(A+B\right)\left(A-B\right)=A^2-B^2$(A+B)(A−B)=A2−B2, we can see that $A=x$A=x and $B=3$B=3. Therefore,
$x^2-9=\left(x+3\right)\left(x-3\right)$x2−9=(x+3)(x−3)
Reflect: Once again, we can check the answer by expanding it. It's always worth checking if an expression fits the pattern $A^2-B^2$A2−B2, because then we can use this special rule. . We call this difference of two squares factorisation. Also notice that it would not make a difference if we said that $B=-3$B=−3.
We can factorise the product of two binomial expressions using the rule $\left(A+B\right)\left(C+D\right)=AC+AD+BC+BD$(A+B)(C+D)=AC+AD+BC+BD.
There are two special cases of factorising these expressions:
- $\left(A+B\right)^2=A^2+2AB+B^2$(A+B)2=A2+2AB+B2 (called a perfect square)
- $\left(A+B\right)\left(A-B\right)=A^2-B^2$(A+B)(A−B)=A2−B2 (called a difference of two squares)
Practice questions
Question 1
Fully factorise: $5\left(a+b\right)+v\left(a+b\right)$5(a+b)+v(a+b)
Question 2
Factorise the following expression by grouping in pairs:
$8x+xz-16y-2yz$8x+xz−16y−2yz
Question 3
Factorise: $n^2-25$n2−25