Constructible root from cubic polynomial

In summary, we use the Rational Roots Theorem to determine the possible rational roots of the cubic polynomial y^3 - 6y^2 + 9y - 27 = 0. By substitution, we can narrow down the list of possible rational roots and ultimately find that there are no rational roots for this polynomial.
  • #1
hanelliot
18
0
Does x^3 - 3x + 3sqrt(3) = have a constructible root?

my solution:
suppose a is a constructible root of the equation above.
we square both sides to get x^6 - 6x^4 + 9x^2 = 27.
since a is constructible, a^2 is constructible as well and we can turn this equation into cubic poly with rational coefficients, and it becomes y^3 - 6y^2 + 9y - 27 = 0.

If this cubic poly has a constructible root, it must have a rational root in form of m/n.
(m/n)^3 - 6(m/n)^2 + 9(m/n) = 27.

How do I proceed from here? Detailed steps would be appreciated..
 
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  • #2
The form will wind up as m^3-6m^2n+9mn^2-27 n^3 =0. This is supposed to be a solution. (We assume that m and n are relatively prime, that is, contain no common factors.) So look at m, there is only 1 term in which it is not present.

So take it from there!
 
  • #3
If it has a rational root, m/n, then m must divide the constant term and n must divide the leading coefficient. Here the constant term is -27 so m must be 1, -1, 3, -3, 9, -9, 27, or -27. The leading coefficient is 1 so the n must be either 1 or -1 which means the only possible rational roots are 1, -1, 3, -3, 9, -9, 27, or -27. Do any of those satisfy the equation?
 
  • #4
You can apply the Rational Roots Theorem to

y^3 - 6y^2 + 9y - 27 = 0.

as HallsofIvy explained, but it is possible to reduce the number of root candidates by substitution.

Define

P(y) = y^3 - 6y^2 + 9y - 27

P(1) = -23, so y = 1 is not a root. Then, instead of trying out the other candidates, you can look at the polynomial:

Q(t) = P(1+t)

The coefficient of t^3 in Q(t) is 1 and the constant term in Q(t) is
Q(0) = P(1) = -23

This means that any rational root of Q(t) must be a divisor of 23, so the possible roots are:

t = 1, -1, 23, -23

The possible rational roots of P(y) are then the values of 1+t which are:

y = 2, 0, 24, -21

But any rational root must also be in the list give by HallsofIvy. Since none of the values for y listed above are on that list, there are no rational roots.
 

1. What is a constructible root from a cubic polynomial?

A constructible root from a cubic polynomial is a number that can be constructed using only a straightedge and compass, starting from a given number and performing basic geometric operations such as drawing lines and circles.

2. What is the significance of constructible roots in mathematics?

Constructible roots have been a subject of study in mathematics since ancient times, as they are related to the classical problem of trisecting an angle. They also have important connections to the field of Galois theory, which studies the properties of polynomials and their roots.

3. Can all cubic polynomials have a constructible root?

No, not all cubic polynomials have a constructible root. In order for a cubic polynomial to have a constructible root, its coefficients must satisfy certain conditions, such as being rational numbers or being able to be expressed using only square roots.

4. How can we determine if a cubic polynomial has a constructible root?

There are several methods for determining if a cubic polynomial has a constructible root. One way is to use the rational root theorem, which states that if a polynomial has a rational root, it must be of the form p/q, where p is a factor of the constant term and q is a factor of the leading coefficient. If this condition is met, the polynomial may have a constructible root.

5. What are some real-life applications of constructible roots from cubic polynomials?

Constructible roots from cubic polynomials have many applications in fields such as geometry, engineering, and architecture. They can be used to solve problems involving trisection of angles, finding the roots of polynomial equations, and constructing geometric figures with precision. They also have applications in computer graphics and animation.

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