4.3: Factoring Trinomials

Example $\PageIndex{1}$:

Factor $x^{2}+12x+20$.

Solution

We begin by writing two sets of blank parentheses. If a trinomial of this form factors, then it will factor into two linear binomial factors.

$x ^ { 2 } + 12 x + 20 = ( \quad ) ( \quad)$

Write the factors of the first term in the first space of each set of parentheses. In this case, factor $x^{2}=x⋅x$.

$x ^ { 2 } + 12 x + 20 = ( x \quad ) ( x\quad )$

Determine the factors of the last term whose sum equals the coefficient of the middle term. To do this, list all of the factorizations of $20$ and search for factors whose sum equals $12$.

$\begin{aligned} 20 & = 1 \cdot 20 \:\:\rightarrow\:\: 1 + 20 = 21 \\ & =\color{OliveGreen}{ 2 \cdot 10 \:\:\rightarrow\:\: 2 + 10}\color{black}{ =}\color{OliveGreen}{ 12} \\ & = 4 \cdot 5 \:\:\:\:\rightarrow\:\: 4 + 5 = 9 \end{aligned}$

Choose $20 = 2 ⋅ 10$ because $2 + 10 = 12$. Write in the last term of each binomial using the factors determined in the previous step.

$x ^ { 2 } + 12 x + 20 = ( x + 2 ) ( x + 10 )$

This can be visually interpreted as follows:

Check by multiplying the two binomials.

$\begin{aligned} ( x + 2 ) ( x + 10 ) & = x ^ { 2 } + 10 x + 2 x + 20 \\ & = x ^ { 2 } + 12 x + 20 \:\:\color{Cerulean}{✓} \end{aligned}$

Answer

$$(x+2)(x+10) \nonumber$$

Example $\PageIndex{2}$:

Factor $x ^ { 2 } y ^ { 2 } - 7 x y + 12$.

Solution

First, factor $x^{2}y^{2}=xy⋅xy$.

$x ^ { 2 } y ^ { 2 } - 7 x y + 12 = ( x y \quad \color{Cerulean}{?}\color{black}{ )} ( x y \quad\color{Cerulean}{?}\color{black}{ )}$

Next, search for factors of $12$ whose sum is $−7$.

$\begin{aligned} 12 & = 1 \cdot 12 \:\:\rightarrow\:\: - 1 + ( - 12 ) = - 13 \\ & = 2 \cdot 6 \:\:\:\:\rightarrow\:\: - 2 + ( - 6 ) = - 8 \\ & = \color{OliveGreen}{3 \cdot 4\:\:\:\: \rightarrow\:\: - 3 + ( - 4 ) = - 7} \end{aligned}$

In this case, choose $−3$ and $−4$ because $(−3)(−4)=+12$ and $−3+(−4)=−7$.

$\begin{aligned} x ^ { 2 } y ^ { 2 } - 7 x y + 12 & = ( x y\quad \color{Cerulean}{?}\color{black}{ )} ( x y\quad\color{Cerulean}{ ?}\color{black}{ )} \\ & = ( x y - 3 ) ( x y - 4 ) \end{aligned}$

Check

$\begin{aligned} ( x y - 3 ) ( x y - 4 ) & = x ^ { 2 } y ^ { 2 } - 4 x y - 3 x y + 12 \\ & = x ^ { 2 } y ^ { 2 } - 7 x y + 12 \:\:\color{Cerulean}{✓} \end{aligned}$

Answer

$( x y - 3 ) ( x y - 4 )$

Example $\PageIndex{3}$:

Factor: $x ^ { 2 } - 4 x y - 12 y ^ { 2 }$.

Solution

Begin by factoring the first term $x ^ { 2 } = x \cdot x$.

$x ^ { 2 } - 4 x y - 12 y ^ { 2 } = \left( \begin{array} { l l } { x } & { \color{Cerulean}{?} } \end{array} \right) \left( \begin{array} { l l } { x } & { \color{Cerulean}{?} } \end{array} \right)$

The factors of $12$ are listed below. In this example, we are looking for factors whose sum is $−4$.

$\begin{aligned} 12 & = 1 \cdot 12 \:\:\rightarrow\:\: 1 + ( - 12 ) = - 11 \\ & =\color{OliveGreen}{ 2 \cdot 6\:\:\:\: \rightarrow\:\: 2 + ( - 6 ) = - 4} \\ & = 3 \cdot 4\:\:\:\: \rightarrow\:\: 3 + ( - 4 ) = - 1 \end{aligned}$

Therefore, the coefficient of the last term can be factored as $−12=2(−6)$, where $2+(−6)=−4$. Because the last term has a variable factor of $y^{2}$, use $−12y^{2}=2y(−6y)$ and factor the trinomial as follows:

$\begin{aligned} x ^ { 2 } - 4 x y - 12 y ^ { 2 } & = ( x \quad \color{Cerulean}{?}\color{black}{ )} ( x \quad \color{Cerulean}{?}\color{black}{ )} \\ & = ( x + 2 y ) ( x - 6 y ) \end{aligned}$

Multiply to check.

$\begin{aligned} ( x + 2 y ) ( x - 6 y ) & = x ^ { 2 } - 6 x y + 2 y x - 12 y ^ { 2 } \\ & = x ^ { 2 } - 6 x y + 2 x y - 12 y ^ { 2 } \\ & = x ^ { 2 } - 4 x y - 12 y ^ { 2 } \:\:\color{Cerulean}{✓}\end{aligned}$

Answer

$( x + 2 y ) ( x - 6 y )$

Example $\PageIndex{4}$:

Factor $a ^ { 2 } + 10 a - 24$.

Solution

The first term of this trinomial, $a^{2}$, factors as $a⋅a$.

$a ^ { 2 } + 10 a - 24 = \left( \begin{array} { l l } { a } & { ? } \end{array} \right) \left( \begin{array} { l l } { a } & { ? } \end{array} \right)$

Consider the factors of $24$:

$\begin{aligned} 24 & = 1 \cdot 24 \\ & = \color{OliveGreen}{2 \cdot 12} \\ & = 3 \cdot 8 \\ & = \color{red}{4 \cdot 6} \end{aligned}$

Suppose we choose the factors $4$ and $6$ because $4 + 6 = 10$, the coefficient of the middle term. Then we have the following incorrect factorization:

$a ^ { 2 } + 10 a - 24 \stackrel{\color{red}{?}}{\color{black}{=}} ( a + 4 ) ( a + 6 ) \:\:\color{red}{Incorrect\:Factorization}$

When we multiply to check, we find the error.

$\begin{aligned} ( a + 4 ) ( a + 6 ) & = a ^ { 2 } + 6 a + 4 a + 24 \\ & = a ^ { 2 } + 10 a \color{red}{+ 24}\:\:\color{red}{✗} \end{aligned}$

In this case, the middle term is correct but the last term is not. Since the last term in the original expression is negative, we need to choose factors that are opposite in sign. Therefore, we must try again. This time we choose the factors $−2$ and $12$ because $−2+12=10$.

$a ^ { 2 } + 10 a - 24 = ( a - 2 ) ( a + 12 )$

Now the check shows that this factorization is correct.

$\begin{aligned} ( a - 2 ) ( a + 12 ) & = a ^ { 2 } + 12 a - 2 a - 24 \\ & = a ^ { 2 } + 10 a \color{OliveGreen}{- 24}\:\:\color{Cerulean}{✓} \end{aligned}$

Answer

$( a - 2 ) ( a + 12 )$

Example $\PageIndex{5}$:

Factor $x ^ { 4 } + 6 x ^ { 2 } + 5$.

Solution

Begin by factoring the first term $x ^ { 4 } = x ^ { 2 } \cdot x ^ { 2 }$.

$x ^ { 4 } + 6 x ^ { 2 } + 5 = \left( x ^ { 2 } \quad \color{Cerulean}{?} \right) \left( x ^ { 2 } \quad \color{Cerulean}{?} \right)$

Since $5$ is prime and the coefficient of the middle term is positive, choose $+1$ and $+5$ as the factors of the last term.

$\begin{aligned} x ^ { 4 } + 6 x ^ { 2 } + 5 & = \left( x ^ { 2 } \quad \color{Cerulean}{?} \right) \left( x ^ { 2 } \quad \color{Cerulean}{?} \right) \\ & = \left( x ^ { 2 } + 1 \right) \left( x ^ { 2 } + 5 \right) \end{aligned}$

Notice that the variable part of the middle term is $x^{2}$ and the factorization checks out.

$\begin{aligned} \left( x ^ { 2 } + 1 \right) \left( x ^ { 2 } + 5 \right) & = x ^ { 4 } + 5 x ^ { 2 } + x ^ { 2 } + 5 \\ & = x ^ { 4 } + 6 x ^ { 2 } + 5\:\:\color{Cerulean}{✓} \end{aligned}$

Answer

$\left( x ^ { 2 } + 1 \right) \left( x ^ { 2 } + 5 \right)$

Example $\PageIndex{6}$:

Factor: $x ^ { 2 n } + 4 x ^ { n } - 21$ where $n$ is a positive integer.

Solution

Begin by factoring the first term $x ^ { 2 n } = x ^ { n } \cdot x ^ { n }$.

$x ^ { 2 n } + 4 x ^ { n } - 21 = \left( \begin{array} { l l } { x ^ { n } } & { \color{Cerulean}{?} } \end{array} \right) \left( \begin{array} { l l } { x ^ { n } } & {\color{Cerulean}{ ?} } \end{array} \right)$

Factor $- 21 = 7 ( - 3 )$ because $7 + ( - 3 ) = + 4$ and write

$\begin{aligned} x ^ { 2 n } + 4 x ^ { n } - 21 & = \left( x ^ { n } \quad \color{Cerulean}{?} \right) \left( x ^ { n } \quad \color{Cerulean}{?} \right) \\ & = \left( x ^ { n } + 7 \right) \left( x ^ { n } - 3 \right) \end{aligned}$

Answer

$$\left( x ^ { n } + 7 \right) \left( x ^ { n } - 3 \right) \nonumber$$

The check is left to the reader.

Example $\PageIndex{7}$

Factor $5 x ^ { 2 } + 16 x y + 3 y ^ { 2 }$.

Solution

Since the leading coefficient and the last term are both prime, there is only one way to factor each.

$5=1⋅5$     and     $3=1⋅3$

Begin by writing the factors of the first term, $5x^{2}$, as follows:

$5 x ^ { 2 } + 16 x y + 3 y ^ { 2 } = ( x \quad \color{Cerulean}{?} \color{black}{)} ( 5 x \quad \color{Cerulean}{?}\color{black}{ )}$

The middle and last term are both positive; therefore, the factors of $3$ are chosen as positive numbers. In this case, the only choice is in which grouping to place these factors.

$(x+y)(5x+3y)$         or        $(x+3y)(5x+y)$

Determine which grouping is correct by multiplying each expression.

$\begin{aligned} ( x + y ) ( 5 x + 3 y ) & = 5 x ^ { 2 } + 3 x y + 5 x y + 3 y ^ { 2 } \\ & = 5 x ^ { 2 } + 8 x y + 3 y ^ { 2 } x \:\:\color{red}{✗} \\ ( x + 3 y ) ( 5 x + y ) & = 5 x ^ { 2 } + x y + 15 x y + 3 y ^ { 2 } \\ & = 5 x ^ { 2 } + 16 x y + 3 y ^ { 2 } \:\:\color{Cerulean}{✓}\end{aligned}$

Answer

$( x + 3 y ) ( 5 x + y )$

Example $\PageIndex{8}$

Factor: $18 a ^ { 2 } b ^ { 2 } - a b - 4$.

Solution

First, consider the factors of the coefficients of the first and last terms.

$\begin{aligned} 18 & = 1 \cdot 18\:\quad4 =\color{OliveGreen}{ 1 \cdot 4} \\ & =\color{OliveGreen}{ 2 \cdot 9} \:\:\:\:\:\quad\color{black}{=} 2 \cdot 2 \\ & = 3 \cdot 6 \end{aligned}$

We are searching for products of factors whose sum equals the coefficient of the middle term, $−1$. After some thought, we can see that the sum of $8$ and $−9$ is $−1$ and the combination that gives this follows:

$2 ( 4 ) + 9 ( - 1 ) = 8 - 9 = - 1$

Factoring begins at this point with two sets of blank parentheses.

$18 a ^ { 2 } b ^ { 2 } - a b - 4 = ( \quad ) (\quad )$

Use $2ab$ and $9ab$ as factors of $18a^{2}b^{2}$.

$18 a ^ { 2 } b ^ { 2 } - a b - 4 = ( 2 a b \quad \color{Cerulean}{?}\color{black}{ )} \:( 9 a b\quad\color{Cerulean}{ ?}\color{black}{ )}$

Next use the factors $1$ and $4$ in the correct order so that the inner and outer products are $−9ab$ and $8ab$ respectively.

$18 a ^ { 2 } b ^ { 2 } - a b - 4 = ( 2 a b - 1 ) ( 9 a b + 4 )$

Answer

$( 2 a b - 1 ) ( 9 a b + 4 )$. The complete check is left to the reader.

Example $\PageIndex{9}$:

Factor $12 y ^ { 3 } - 26 y ^ { 2 } - 10 y$.

Solution

Begin by factoring out the GCF.

$12 y ^ { 3 } - 26 y ^ { 2 } - 10 y = 2 y \left( 6 y ^ { 2 } - 13 y - 5 \right)$

After factoring out $2y$, the coefficients of the resulting trinomial are smaller and have fewer factors. We can factor the resulting trinomial using $6=2(3)$ and $5=(5)(1)$. Notice that these factors can produce $−13$ in two ways:

$\begin{array} { l } { 2 ( - 5 ) + 3 ( - 1 ) = - 10 - 3 = - 13 } \\ { 2 ( \color{OliveGreen}{1}\color{black}{ )} + 3 (\color{OliveGreen}{ - 5}\color{black}{ )} = 2 - 15 = - 13 } \end{array}$

Because the last term is $−5$, the correct combination requires the factors $1$ and $5$ to be opposite signs. Here we use $2(1) = 2$ and $3(−5) = −15$ because the sum is $−13$ and the product of $(1)(−5) = −5$.

$\begin{aligned} 12 y ^ { 3 } - 26 y ^ { 2 } - 10 y & = 2 y \left( 6 y ^ { 2 } - 13 y - 5 \right) \\ & = 2 y ( 2 y\quad \color{Cerulean}{?}\color{black}{ )} ( 3 y\quad\color{Cerulean}{ ?}\color{black}{ )} \\ & = 2 y ( 2 y - 5 ) ( 3 y + 1 ) \end{aligned}$

Check.

$\begin{aligned} 2 y ( 2 y - 5 ) ( 3 y + 1 ) & = 2 y \left( 6 y ^ { 2 } + 2 y - 15 y - 5 \right) \\ & = 2 y \left( 6 y ^ { 2 } - 13 y - 5 \right) \\ & = 12 y ^ { 3 } - 26 y ^ { 2 } - 10 y\color{Cerulean}{✓} \end{aligned}$

The factor $2y$ is part of the factored form of the original expression; be sure to include it in the answer.

Answer

$2 y ( 2 y - 5 ) ( 3 y + 1 )$

Example $\PageIndex{10}$

Factor: $- 18 x ^ { 6 } - 69 x ^ { 4 } + 12 x ^ { 2 }$.

Solution

In this example, the GCF is $3x^{2}$. Because the leading coefficient is negative we begin by factoring out $−3x^{2}$.

$- 18 x ^ { 6 } - 69 x ^ { 4 } + 12 x ^ { 2 } = - 3 x ^ { 2 } \left( 6 x ^ { 4 } + 23 x ^ { 2 } - 4 \right)$

At this point, factor the remaining trinomial as usual, remembering to write the $−3x^{2}$ as a factor in the final answer. Use $6 = 1(6)$ and $−4 = 4(−1)$because $1(−1)+6(4)=23$. Therefore,

$\begin{aligned} - 18 x ^ { 6 } - 69 x ^ { 4 } + 12 x ^ { 2 } & = - 3 x ^ { 2 } \left( 6 x ^ { 4 } + 23 x ^ { 2 } - 4 \right) \\ & = - 3 x ^ { 2 } \left( x ^ { 2\quad } \right) \left( 6 x ^ { 2 }\quad \right) \\ & = - 3 x ^ { 2 } \left( x ^ { 2 } + 4 \right) \left( 6 x ^ { 2 } - 1 \right) \end{aligned}$

Answer

$- 3 x ^ { 2 } \left( x ^ { 2 } + 4 \right) \left( 6 x ^ { 2 } - 1 \right)$. The check is left to the reader.

Example $\PageIndex{11}$:

Factor using the AC method: $18 x ^ { 2 } - 31 x + 6$.

Solution

Here $a=18, b=-31$, and $c=6$.

$\begin{aligned} a c & = 18 ( 6 ) \\ & = 108 \end{aligned}$

Factor $108$, and search for factors whose sum is $−31$.

$$\begin{aligned} 108 & = - 1 ( - 108 ) \\ & = - 2 ( - 54 ) \\ & = - 3 ( - 36 ) \\ & =\color{OliveGreen}{ - 4 ( - 27 )}\color{Cerulean}{✓} \\ & \color{black}{=} - 6 ( - 18 ) \\ & = - 9 ( - 12 ) \end{aligned}$$

In this case, the sum of the factors $−27$ and $−4$ equals the middle coefficient, $−31$. Therefore, $−31x=−27x−4x$, and we can write

$18 x ^ { 2 } \color{OliveGreen}{- 31 x}\color{black}{ +} 6 = 18 x ^ { 2 } \color{OliveGreen}{- 27 x - 4 x}\color{black}{ +} 6$

Factor the equivalent expression by grouping.

$\begin{aligned} 18 x ^ { 2 } - 31 x + 6 & = 18 x ^ { 2 } - 27 x - 4 x + 6 \\ & = 9 x ( 2 x - 3 ) - 2 ( 2 x - 3 ) \\ & = ( 2 x - 3 ) ( 9 x - 2 ) \end{aligned}$

Answer

$( 2 x - 3 ) ( 9 x - 2 )$

Example $\PageIndex{12}$:

Factor using the AC method: $4 x ^ { 2 } y ^ { 2 } - 7 x y - 15$.

Solution

Here $a=4, b= -7$, and $c=-15$.

$\begin{aligned} a c & = 4 ( - 15 ) \\ & = - 60 \end{aligned}$

Factor $−60$ and search for factors whose sum is $−7$.

$\begin{aligned} - 60 & = 1 ( - 60 ) \\ & = 2 ( - 30 ) \\ & = 3 ( - 20 ) \\ & = 4 ( - 15 ) \\ & = \color{OliveGreen}{5 ( - 12 )}\:\:\color{Cerulean}{✓} \\ & = 6 ( - 10 ) \end{aligned}$

The sum of factors $5$ and $−12$ equals the middle coefficient, $−7$. Replace $−7xy$ with $5xy−12xy$.

$\begin{aligned} 4 x ^ { 2 } y ^ { 2 } - 7 x y - 15 & = 4 x ^ { 2 } y ^ { 2 } + 5 x y - 12 x y - 15\quad\color{Cerulean}{Factor\:by\:grouping.} \\ & = x y ( 4 x y + 5 ) - 3 ( 4 x y + 5 ) \\ & = ( 4 x y + 5 ) ( x y - 3 ) \end{aligned}$

Answer

$$( 4 x y + 5 ) ( x y - 3 ).$$

The check is left to the reader.