Need help. (1 Viewer)

123ryoma12 · Oct 17, 2016

Ok, so the question isn't the problem but rather the method used to get the answer.
This is the answer:

Why is it that we're allowed to take the modulus of both sides to get a locus because if I do the same with a fixed point for example:
z = 1 + i
|z| = sqrt(2)
x^2 + y^2 = 2
I get that locus, which is obviously wrong because z is a fixed point.

Paradoxica · Oct 17, 2016

123ryoma12 said:
View attachment 33512
Ok, so the question isn't the problem but rather the method used to get the answer.
This is the answer:
View attachment 33513
Why is it that we're allowed to take the modulus of both sides to get a locus because if I do the same with a fixed point for example:
z = 1 + i
|z| = sqrt(2)
x^2 + y^2 = 2
I get that locus, which is obviously wrong because z is a fixed point.

Your "counterexample" doesn't work because there is no variable.

In the question you are flummoxing over, there are two variables, and you are given the behaviour of one.

The relation between the variables is given and you are asked to determine the behaviour of the dependent variable.

InteGrand · Oct 17, 2016

123ryoma12 said:
View attachment 33512
Ok, so the question isn't the problem but rather the method used to get the answer.
This is the answer:
View attachment 33513
Why is it that we're allowed to take the modulus of both sides to get a locus because if I do the same with a fixed point for example:
z = 1 + i
|z| = sqrt(2)
x^2 + y^2 = 2
I get that locus, which is obviously wrong because z is a fixed point.

$\noindent Yeah, technically the answer as written just shows that if $|z_1| = 1$, then $|z_2| = \sqrt{11}$. One way to see that the whole circle is obtained is as follows. Let $w = \sqrt{2} - 3i = R\,\mathrm{cis}\left(\phi\right)$, where $R = \sqrt{11}$ and $\phi = \mathrm{Arg}\left(w\right)$. Write $z_1 = \mathrm{cis}(\theta)$ (since modulus is $1$). Now, $z_{2} = \frac{w}{z_{1}} = R\,\mathrm{cis} \left(\phi - \theta\right)$. So as $\theta$ varies through the real numbers, $z_{2}$ has fixed modulus $R = \sqrt{11}$ and its argument takes on all real values (since $\phi - \theta$ takes on all real values). In other words, $z_{2}$ will trace out the circle $x^{2} + y^{2} = 11$.$

InteGrand · Oct 17, 2016

123ryoma12 · Oct 17, 2016

ok tyty

Need help. (1 Viewer)

123ryoma12

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Paradoxica

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InteGrand

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InteGrand

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123ryoma12

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