2x² + 9x − 5
-- it will be factored as a product of binomials:
(? ?)(? ?)
Now, how will 2x² be produced? There is only one way: 2x· x :
(2x ?)(x ?)
And how will 5 be produced? Again, there is only one
way: 1· 5. But does the 5 go with 2x or with x ?
(2x 5)(x 1) or
(2x 1)(x 5) ?
Notice: We have not yet placed any signs!
How shall we decide between these two possibilities? It is the combination that will correctly give the middle term, 9x.
Let us consider the first possibility:
(2x 5)(x 1)
Is it possible to produce 9x by combining the outers and the inners: 2x· 1 with 5x ?
No, it is not. Therefore, we must eliminate that possibility and consider the other:
(2x 1)(x 5)
Can we produce 9x by combining 10x with x ?
Yes -- if we choose +5 and −1:
(2x − 1)(x + 5)
(2x − 1)(x + 5) = 2x² + 9x − 5
Skill in factoring depends on skill in multiplying -- particularly in picking out the middle term!
Problem 1. Place the correct signs to give the middle term.
a) 2x² + 7x − 15 = (2x
− 3)(x
+ 5)
b) 2x² − 7x − 15 = (2x
+ 3)(x
− 5)
c) 2x² − x − 15 = (2x
+ 5)(x
− 3)
d) 2x² − 13x + 15 = (2x
− 3)(x
− 5)
Note: When the constant term is negative, as in parts a), b), c), then the signs will be different. But when that term is positive, as in part d), the signs will be the same. Usually, however, that happens by itself.
Nevertheless, can you correctly factor the following?
2x² − 5x + 3
= (2x − 3)(x − 1)
Problem 2. Factor these trinomials.
a) 3x² + 8x + 5
= (3x + 5)(x + 1)
b) 3x² + 16x + 5
= (3x + 1)(x + 5)
c) 2x² + 9x + 7
= (2x + 7)(x + 1)
d) 2x² + 15x + 7
= (2x + 1)(x + 7)
e) 5x² + 8x + 3
= (5x + 3)(x + 1)
f) 5x² + 16x + 3
= (5x + 1)(x + 3)
Problem 3. Factor these trinomials.
a) 2x² − 7x + 5
= (2x − 5)(x − 1)
b) 2x² − 11x + 5
= (2x − 1)(x − 5)
c) 3x² + x − 10
= (3x − 5)(x + 2 )
d) 2x² − x − 3
= (2x − 3)(x + 1)
e) 5x² − 13x + 6
= (5x − 3)(x − 2)
f) 5x² − 17x + 6
= (5x − 2)(x − 3)
g) 2x² + 5x − 3
= (2x − 1)(x + 3)
h) 2x² − 5x − 3
= (2x + 1)(x − 3)
i) 2x² + x − 3
= (2x + 3)(x − 1)
j) 2x² − 13x + 21
= (2x − 7 )(x −3)
k) 5x² − 7x − 6
= (5x + 3)(x − 2)
i) 5x² − 22x + 21
= (5x − 7)(x − 3)
Example 1. 1 the coefficient of x². Factor x² + 3x − 10.
Solution. The binomial factors will have this form:
(x a)(x b)
What are the factors of 10? Let us hope that they are 2 and 5:
x² + 3x − 10 = (x 2)(x 5)
We must now choose the signs so that the coefficient of the middle term will be +3. Choose −2 and + 5.
x² + 3x − 10 = (x − 2)(x + 5)
Note: When 1 is the coefficient of x², the order of the factors does not matter.
x² + 3x − 10 = (x + 5) (x − 2)
Example 2. Factor x² − x − 12.
Solution. We must find factors of 12 whose algebraic sum will be the coefficient of x : −1. Choose −4 and + 3:
x² − x − 12 = (x − 4 )(x + 3)
Problem 4. Factor. Again, the order of the factors does not matter.
a) x² + 5x + 6
= (x + 2)(x + 3)
b) x² − x − 6
= (x − 3 )(x + 2)
c) x² + x − 6
= (x + 3 )(x − 2)
d) x² − 5x + 6
= (x − 3)(x − 2 )
e) x² + 7x + 6
= (x + 1)(x + 6 )
f) x² − 7x + 6
= (x − 1)(x − 6 )
g) x² + 5x − 6
= (x − 1)(x + 6 )
h) x² − 5x − 6
= (x + 1)(x − 6 )
Problem 5. Factor.
a) x² − 10x + 9
= (x − 1 )(x − 9)
b) x² + x − 12
= (x + 4)(x − 3)
c) x² − 6x − 16
= (x − 8)(x + 2)
d) x² − 5x − 14
= (x − 7)(x + 2)
e) x² − x − 2
= (x + 1)(x − 2)
f) x² − 12x + 20
= (x − 10 )(x − 2)
g) x² − 14x + 24
= (x − 12 )(x − 2)
Example 3. Factor completely 6x8 + 30x7 + 36x6.
Solution. To factor completely means to first remove any common factors (Lesson 15).
Quadratics in different arguments
Here is the form of a quadratic trinomial with argument x :
ax² + bx + c
The argument is whatever is being squared. x is being squared. x is the argument. The argument appears in the middle term.
a, b, c are called constants. In this quadratic,
3x² + 2x − 1,
the constants are 3, 2, −1.
Now here is a quadratic whose argument is x3:
3x6 + 2x3 − 1.
x6 is the square of x3. (Lesson 13: Exponents.)
But that quadratic has the same constants as the one above. In a sense, it is the same quadratic only with a different argument. For it is the constants that characterize the quadratic.
Now, since the quadratic with argument x can be factored as
3x² + 2x − 1 = (3x − 1)(x + 1),
so can the quadratic with argument x3:
3x6 + 2x3 − 1 = (3x3 − 1)(x3 + 1).
If z is the argument of any quadratic with constants 3, 2, −1, then
3z² + 2z − 1 = (3z − 1)(z + 1).
The trinomials on the right have the same constants 1, −3, −10 but different arguments. That is the only difference between them. In the first, the argument is z. In the second, the argument is x4.
Every quadratic with constants 1, −3, −10 will be factored that way.