Complex/surd conjugates (1 Viewer)

chanandlerbong · Jan 25, 2016

My question:
I know that if the coefficients of P(x) is real, that means the complex conjugate is real if there is a complex root.
However, what if there is a surd root? e.g root5, would the conjugate -root5 also be a root?

KingOfActing · Jan 25, 2016

chanandlerbong said:
My question:
I know that if the coefficients of P(x) is real, that means the complex conjugate is real if there is a complex root.
However, what if there is a surd root? e.g root5, would the conjugate -root5 also be a root?

I'm not quite sure I understand what you're asking. If we're given some polynomial P with real coefficients, and we know $P(a+bi) = 0$ , then by the complex conjugate root theorem, we also know $P(a-bi) = 0$ .

On the other hand, by the irrational conjugate root theorem, if we are given a polynomial P with rational coeffecients, and $P(a+b\sqrt{c})=0$ then we also know $P(a-b\sqrt{c})=0$ , given that a, b and c are all rational, and c is not a perfect square.

chanandlerbong · Jan 26, 2016

When you say rational coefficients, you mean where numbers can be expressed as a fraction right? Also, I have another question:

P(z) = z^4 + (1-2i)z^2 -2i.
i is a root of this equation. Explain why -i is also a root.

I can't talk about the conjugate root theorem right? So how do I explain this? Do I talk about how P(z) has even powers, therefore it's an even function? So -i is also a root? I'm a little confused

Paradoxica · Jan 26, 2016

chanandlerbong said:
When you say rational coefficients, you mean where numbers can be expressed as a fraction right? Also, I have another question:

P(z) = z^4 + (1-2i)z^2 -2i.
i is a root of this equation. Explain why -i is also a root.

I can't talk about the conjugate root theorem right? So how do I explain this? Do I talk about how P(z) has even powers, therefore it's an even function? So -i is also a root? I'm a little confused

Yes, even powers, because the 2n-th power of i is equal to the 2n-th power of -i.

In an even polynomial, if a is a root, then -a is a root, without regards to complex/real roots.

That or direct substitution.

InteGrand · Jan 26, 2016

chanandlerbong said:
When you say rational coefficients, you mean where numbers can be expressed as a fraction right? Also, I have another question:

P(z) = z^4 + (1-2i)z^2 -2i.
i is a root of this equation. Explain why -i is also a root.

I can't talk about the conjugate root theorem right? So how do I explain this? Do I talk about how P(z) has even powers, therefore it's an even function? So -i is also a root? I'm a little confused

$\noindent For this one, the only powers of $z$ present in $P(z)$ are even powers. Hence if $\alpha$ is a root, then so is $-\alpha$, since $P(\alpha) =P(-\alpha)$, since raising a negative of a number to an even power is the same as raising that number without the negative sign. In other words, $\alpha ^{2k} = (-\alpha)^{2k}$ for any positive integer $k$ (and any complex number $\alpha$, regardless of whether it is a root or not).$

Edit: said above

Complex/surd conjugates (1 Viewer)

chanandlerbong

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KingOfActing

lukewarm mess

chanandlerbong

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Paradoxica

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InteGrand

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