Complex Numbers / Polynomials Q (1 Viewer)

mreditor16 · Mar 23, 2015

if I have w as a complex root of z^5 = 1, then how would you express the conjugate of (w + w^4) in terms of positive powers of w

(Asking on behalf of a friend)

InteGrand · Mar 23, 2015

mreditor16 · Mar 23, 2015

Let me rephrase my original Q -

I am stuck on part ii)

InteGrand · Mar 23, 2015

By the conjugate root theorem, the other root is $\overline{\omega + \omega ^4}=\omega^4 + \omega =\alpha$ (i.e. double root).

Sy123 · Mar 23, 2015

mreditor16 said:
uh nah :/

here's the original Q - I'm stuck on part ii)

Do you wanna reply on new thread? Feel bad for posting this on NS.

I have a feeling that there is a typo in the question and that $\alpha = w + w^2$

Because as it is being asked now, the answers are trivial, and they don't even aid in getting part (iv)

InteGrand · Mar 23, 2015

Part (iii) asks something about a – what's a? Do they mean find the values of b and c?

mreditor16 · Mar 23, 2015

InteGrand said:
By the conjugate root theorem, the other root is $\overline{\omega + \omega ^4}=\omega^4 + \omega =\alpha$ (i.e. double root).

Noob Q here (because I've forgotten my shit) - how is conjugate of w equal to w^4 ?

mreditor16 · Mar 23, 2015

InteGrand said:
Part (iii) asks something about a – what's a? Do they mean find the values of b and c?

I assume so

Sy123 · Mar 23, 2015

mreditor16 said:
Noob Q here (because I've forgotten my shit) - how is conjugate of w equal to w^4 ?

I am willing to bet that there is a typo in what $\alpha$ is supposed to be

$\alpha = w + w^2$ makes more sense with part (iv)

Anyway, for a complex number z, its conjugate is such that z*conj(z) = real number

So, since $w \cdot w^4 = w^5 = 1$ thus w and w^4 are conjugates

mreditor16 · Mar 23, 2015

Sy123 said:
I am willing to bet that there is a typo in what $\alpha$ is supposed to be

$\alpha = w + w^2$ makes more sense with part (iv)

Anyway, for a complex number z, its conjugate is such that z*conj(z) = real number

So, since $w \cdot w^4 = w^5 = 1$ thus w and w^4 are conjugates

Omg I feel so stupid - I still don't get it.

Sy123 · Mar 23, 2015

mreditor16 said:
Omg I feel so stupid - I still don't get it.

So remember that w is a root of z^5 = 1

This means that w^5 = 1, right?

Since w^5 = 1

and w^4*w = w^5 (since when we multiply them the powers add)

thus w^4 * w = 1

So what we have here is 2 complex numbers, that multiplied together get a real number (and both complex numbers have the same modulus), therefore they are conjugates of each other

meaning

$w = \overline{w^4}$

seanieg89 · Mar 23, 2015

Sy123 said:
I am willing to bet that there is a typo in what $\alpha$ is supposed to be

$\alpha = w + w^2$ makes more sense with part (iv)

Anyway, for a complex number z, its conjugate is such that z*conj(z) = real number

So, since $w \cdot w^4 = w^5 = 1$ thus w and w^4 are conjugates

Definitely. The question doesn't make sense as is, the conjugate root theorem tells us nothing if one of the roots is real. Beta can be absolutely anything.

mreditor16 · Mar 23, 2015

Sy123 said:
So remember that w is a root of z^5 = 1

This means that w^5 = 1, right?

Since w^5 = 1

and w^4*w = w^5 (since when we multiply them the powers add)

thus w^4 * w = 1

So what we have here is 2 complex numbers, that multiplied together get a real number (and both complex numbers have the same modulus), therefore they are conjugates of each other

meaning

$w = \overline{w^4}$

How can we just make that assumption? What if there is another complex number multiplied by w which gives a (different) real number?

InteGrand · Mar 23, 2015

mreditor16 said:
How can we just make that assumption? What if there is another complex number multiplied by w which gives a (different) real number?

$\omega = \mathrm{cis} \left( \frac{2k\pi}{5}\right )$ for some $k\in \mathbb{Z}$ such that $k\neq 5m$ for $m\in \mathbb{Z}$ .

$\omega^4 = \mathrm{cis} \left( \frac{8k\pi}{5}\right )=\mathrm{cis} \left( -\frac{2k\pi}{5}\right )}=\overline{\omega}$ , since $\frac{8k\pi}{5}$ differs from $\frac{-2k\pi}{5}$ by a multiple of $2\pi$ .

Sy123 · Mar 23, 2015

mreditor16 said:
How can we just make that assumption? What if there is another complex number multiplied by w which gives a (different) real number?

Well it comes directly from the definition

Two conjugates of each other are defined as:

$z = r(\cos \theta + i\sin \theta)$

$\overline{z} = r(\cos (-\theta) i\sin (-\theta))$

$z \cdot \overline{z} = r^2 (\cos(\theta -\theta) + i\sin(\theta - \theta)) = r^2$

So, if I have 2 complex numbers of the same modulus, and when multiplied they become a real number, it means the arguments of the complex numbers add up to zero, this means their arguments are opposite in sign.

And by definition 2 complex numbers of equal modulus and arguments opposite in sign are conjugates of each other

seanieg89 · Mar 23, 2015

mreditor16 said:
How can we just make that assumption? What if there is another complex number multiplied by w which gives a (different) real number?

Remember the rule

$z\overline{z}=|z|^2?$

This implies for nonzero z:

$z^{-1}=\frac{\overline{z}}{|z|^2}.$

In particular, inverting is the same thing as taking conjugates on the unit circle.

For example

$\overline{w}=w^{-1}=w^5/w=w^4$

if w is a 5-th root of unity.

mreditor16 · Mar 23, 2015

I get it guys. Thank you so much!!!

Complex Numbers / Polynomials Q (1 Viewer)

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