College Algebra - Equations Reducible to Quadratic Form

Give the complete solution set for the equation:

$x^{4} + 8x^{2} + 12 = 0$

$\left { - i \sqrt{6}, - i \sqrt{2}, i \sqrt{2} , i \sqrt{6} \right }$

$\left { - \sqrt{6}, - \sqrt{2}, \sqrt{2} , \sqrt{6} \right }$

$\left { -2 i , - i \sqrt{3}, i \sqrt{3} ,2 i \right }$

$\left { - 2, - \sqrt{3}, \sqrt{3} ,2 \right }$

$\left { -2 i \sqrt{3}, - i , i ,2 i \sqrt{3}\right }$

Explanation

$x^{4} + 8x^{2} + 12 = 0$

can be rewritten in quadratic form by setting $u = x^{2}$ , and, consequently, $u^{2} = x^{4}$ ; the resulting equation is as follows:

$u^{2} + 8u+ 12 = 0$

By the reverse-FOIL method we can factor the trinomial at left. We are looking for two integers with sum 8 and product 12; they are 2 and 6, so the equation becomes

Setting both binomials equal to 0, it follows that

or .

Substituting $x^{2}$ for , we get

$x^{2} = -2$ ,

in which case

$x = \pm i \sqrt{2}$ ,

or $x^{2} = -2$

in which case

$x = \pm i \sqrt{6}$ .

The solution set is $\left { - i \sqrt{6}, - i \sqrt{2}, i \sqrt{2} , i \sqrt{6} \right }$ .

Give the complete set of real solutions for the equation:

$e^{2x}- 8e^{x}+ 12 = 0$

$\left { \ln 2, \ln 6 \right }$

$\left { 0, \ln 12 \right }$

$\left { \ln 3 , \ln 4 \right }$

The equation has no solutions.

Explanation

$e^{2x}- 8e^{x}+ 12 = 0$

can be rewritten in quadratic form by setting $u = e^{x}$ , and, consequently, $u^{2} =( e^{x})^{2} = e^{2x}$ ; the resulting equation is as follows:

$u^{2} - 8u+ 12 = 0$

By the reverse-FOIL method we can factor the trinomial at left. We are looking for two integers with sum 8 and product 12; they are and , so the equation becomes

Setting both binomials equal to 0, it follows that

or .

Substituting $e^{x}$ for , we get

$e^{x} = 2$

in which case

$x = \ln 2$ ,

and

$e^{x} = 6$ ,

in which case

$x = \ln 6$

The set of real solutions is therefore $\left { \ln 2, \ln 6 \right }$ .

Find all real roots of the polynomial function

$x = \left { -1,0,1\right }$

$x = \left { -1,1\right }$

(There are no nonzero solutions)

$x = \left { -2,-1,0,1,2\right }$

$x = \left { 0,1\right }$

Explanation

Find the roots of the polynomial,

Set equal to

Factor out ,

Notice that the the factor is a quadratic even though it might not seem so at first glance. One way to think of this is as follows:

Let

Then we have , substitute into to get,

Notice that the change in variable from to has resulted in a quadratic equation that can be easily factored due to the fact that it is a square of a simple binomial:

The solution for is,

Because we go back to the variable ,

Therefore, the roots of the factor are,

$x = \pm 1$

The other root of is since the function clearly equals when .

The solution set is therefore, $x = \left { -1,0,1\right }$

Below is a plot of . You can see where the function intersects the -axis at points corresponding to our solutions.

Further Discussion

The change of variable was a tool we used to write the quadratic factor in a more familiar form, but we could have just factored the original function in terms of as follows,