Functions: Higher degree polynomials
Solving higher degree polynomials with the quadratic formula
Some equations with polynomials can be solved with the quadratic formula. For that, we use substitution.
|
Procedure We solve an equation with polynomials in #x# with the quadratic formula. |
Example #2x^4+3x^2-2=0# |
|
| Step 1 | Write the equation in the form #a \blue x^{\blue n \cdot 2}+b \blue{x^n} +c=0#. | #2\blue{x}^{\blue2 \cdot 2}+3\blue{x^2}-2=0# |
| Step 2 | Substitute #\blue{x^n}=\green u#. | #2\green u^2+3\green u-2=0# |
| Step 3 | Solve the obtained quadratic equation in #\green u# with the quadratic formula. | #\green u=-2 \lor \green u =\tfrac{1}{2}# |
| Step 4 | Substitute #\green u =\blue{x^n}# in the found solution(s). | #\blue{x^2}=-2 \lor \blue{x^2}=\tfrac{1}{2}# |
| Step 5 | Determine the solutions in #x# from the equations obtained in step 4. | #x=-\tfrac{1}{\sqrt{2}} \lor x=\tfrac{1}{\sqrt{2}}# |
#x=\sqrt[5]{-{{8}\over{3}}} \lor x=\sqrt[5]{-{{4}\over{3}}} #
| Step 1 | We write the equation in the form: \[9 x^{2 \cdot 5}+36 x^{5}+32=0\] |
| Step 2 | We substitute #x^5=u#. This gives: \[9 u^2+36 u+32=0\] |
| Step 3 | We solve the obtained equation in #u# by means of the quadratic formula. The discriminant is equal to: \[\begin{array}{rcl}D&=&b^2-4ac \\ &&\phantom{xxx}\blue{\text{formula for the discriminant}}\\ &=& \left(36\right)^2-4 \cdot 9 \cdot 32 \\ &&\phantom{xxx}\blue{\text{formula entered}}\\ &=& 144 \\ &&\phantom{xxx}\blue{\text{calculated}}\end{array}\] Since the discriminant is positive, there are two solutions. These are: \[\begin{array}{rcl}u=\frac{-b-\sqrt{D}}{2a} &\lor& u=\frac{-b+\sqrt{D}}{2a} \\ &&\phantom{xxx}\blue{\text{formula for the solutions}}\\ u=\frac{-{36}-\sqrt{144}}{2 \cdot 9} &\lor& u=\frac{-{36}+\sqrt{144}}{2 \cdot 9}\\ &&\phantom{xxx}\blue{\text{formula entered}}\\ u=-{{8}\over{3}} &\lor& u=-{{4}\over{3}} \\ &&\phantom{xxx}\blue{\text{calculated}}\end{array}\] |
| Step 4 | Now we substitute #u=x^{5}# in the found solutions, this gives us \[x^{5}=-{{8}\over{3}} \lor x^{5}=-{{4}\over{3}}\] |
| Step 5 | Finally we solve these equations by taking the root. This gives us the solutions to the original equation: \[x=\sqrt[5]{-{{8}\over{3}}} \lor x=\sqrt[5]{-{{4}\over{3}}}\] |
Unlock full access
Teacher access
Request a demo account. We will help you get started with our digital learning environment.
