Find all roots [meaning both real and complex].
f(x)=4x^5 + 2x^3 - 3x
Factor
f(x)=x(4x^4 + 2x^2 - 3)
Quadratic Formula (Modified to fit the fourth degree equation)
x^2 = [-b +/- sqrt (b^2 - 4ac)] / 2a
Let a = 4, b = 2, c = -3
x^2 = {-2 +/- sqrt [4 - 4(4)(-3)]} / 2(4)
x^2 = [-1 + sqrt (13)] / 4
Therefore, the real roots are
x = 0 from the factoring above
x = {+/- sqrt [-1 + sqrt (13)] } / 2 from the quadratic formula
I checked these on a calculator.
Now, here's the real question. Trying to use synthetic division to factor the equation to a quadratic, from which the imaginary conjugate can be found, is a complete mess.
How can I divide 4x^4 + 2x^2 - 3 by {+/- sqrt [-1 + sqrt (13)] } / 2 to "factor" it down to x times x - [sqrt [-1 + sqrt (13)] / 2] times x + [sqrt [-1 + sqrt (13) /2] times a second degree factor?
In other words, do I simply have to put up with the messy synthetic division, or is there a simpler approach?
f(x)=4x^5 + 2x^3 - 3x
Factor
f(x)=x(4x^4 + 2x^2 - 3)
Quadratic Formula (Modified to fit the fourth degree equation)
x^2 = [-b +/- sqrt (b^2 - 4ac)] / 2a
Let a = 4, b = 2, c = -3
x^2 = {-2 +/- sqrt [4 - 4(4)(-3)]} / 2(4)
x^2 = [-1 + sqrt (13)] / 4
Therefore, the real roots are
x = 0 from the factoring above
x = {+/- sqrt [-1 + sqrt (13)] } / 2 from the quadratic formula
I checked these on a calculator.
Now, here's the real question. Trying to use synthetic division to factor the equation to a quadratic, from which the imaginary conjugate can be found, is a complete mess.
How can I divide 4x^4 + 2x^2 - 3 by {+/- sqrt [-1 + sqrt (13)] } / 2 to "factor" it down to x times x - [sqrt [-1 + sqrt (13)] / 2] times x + [sqrt [-1 + sqrt (13) /2] times a second degree factor?
In other words, do I simply have to put up with the messy synthetic division, or is there a simpler approach?
