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The expression can be written as $$\frac{1+z}{\overline {1+z}}$$

Since $z \cdot \overline z=|z|^2$ $$\overline{1+z}= \frac{1}{1+z}$$ As $|z|=1$

So it will become $(1+z)^2$

But the answer is $z$. What am I doing wrong?

inavda
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Aditya
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    You can write $\overline{1 + z}$ via the $LaTeX$ "$\overline{1 + z}$"; note we use "\overline" and not "\bar". (which giives a short bar and won't go over all of $1 + z$). Don't forget the braces. Cheers! – Robert Lewis Oct 16 '19 at 16:05
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    Suggested an edit to fix the LaTeX formatting: using \bar puts a fixed-width bar over the character; using \overline puts a bar that extends to cover the whole length of the expression. – inavda Oct 16 '19 at 16:06
  • Got it! Will keep that in mind – Aditya Oct 16 '19 at 16:07
  • "then the $\frac{1 + z}{\overline{1 + z}}$ . . . .is what? I guess you mean it is also unimodular, but if complete sentences work for former President Obama, they will for you. ;) Cheers! . . – Robert Lewis Oct 16 '19 at 16:09
  • Fixed it. Cheers! – Aditya Oct 16 '19 at 16:10
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    Great! Thanks for responding. Good edits! – Robert Lewis Oct 16 '19 at 16:11

3 Answers3

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You are asserting that if $z\cdot \overline z=1$ then $(1+\overline z)(1+z)=1,$ too. That is not true. A simple case is $z=1.$

Being unimodular means $z\cdot \overline{z}=1.$ Then $\overline z = z^{-1}.$

So $$\frac{1+z}{1+\overline{z}}=\frac{1+z}{1+z^{-1}}=\frac{1+z}{1+z^{-1}}\cdot \frac z z=\frac{z(1+z)}{z+1}=z$$

Note, the left side is not defined in the case $z=-1.$

Thomas Andrews
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Assume $z=e^{i\theta}$ therefore

$$\frac{1+z}{1+\bar z}=\frac{1+e^{i\theta}}{1+e^{-i\theta}}=\frac{e^{i\theta}(1+e^{i\theta})}{e^{i\theta}(1+e^{-i\theta})}=\frac{e^{i\theta}(1+e^{i\theta})}{e^{i\theta}+1}=e^{i\theta}$$

which is valid for $z\neq -1$.

user
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Note that for any

$\chi \in \Bbb C \tag 1$

we have

$\vert \chi \vert = \vert \bar \chi \vert; \tag 2$

this is easily seen by writing

$\chi = a + bi; \tag 3$

then

$\bar \chi = a - bi; \tag 4$

thus,

$\vert \chi \vert = \sqrt{a^2 + b^2} = \vert \bar \chi \vert; \tag 5$

or, if one prefers polars,

$\chi = re^{i\theta}, \; \bar \chi = re^{-i\theta}, \tag 6$

and so

$\vert \chi \vert = \vert re^{i\theta} \vert = r \vert e^{i\theta} \vert = r = r \vert e^{-i\theta} \vert = \vert re^{-i\theta} \vert = \vert \bar \chi \vert; \tag 7$

so if

$\chi \ne 0, \tag 8$

$\left \vert \dfrac{\chi}{\bar \chi} \right \vert = \dfrac{\vert \chi \vert}{\vert \bar \chi \vert} = 1; \tag 8$

we finish off by setting

$\chi = 1 + z \tag 9$

(assuming of course $z \ne -1$), whence

$\bar \chi = \overline{1 + z} = 1 + \bar z, \tag{10}$

whence

$\left \vert \dfrac{1 + z}{{1 + \bar z}} \right \vert = \left \vert \dfrac{1 + z}{\overline{1 + z}} \right \vert = 1. \tag{11}$

Finally, if we write

$1 + z = re^{i\theta}, \tag{12}$

we find

$1 + \bar z = \overline{1 + z} = re^{-i\theta}, \tag{13}$

and so

$\left \vert \dfrac{1 + z}{\overline{1 + z}} \right \vert = \left \vert \dfrac{re^{i\theta}}{re^{-i\theta}} \right \vert = \vert e^{2i\theta} \vert = 1. \tag{14}$

With

$\vert z \vert = 1, \tag{15}$

$z = e^{i\theta}, \; \bar z = e^{-i\theta}, \tag{16}$

so

$\dfrac{1 + z}{1 + \bar z} = \dfrac{1 + e^{i\theta}}{1 + e^{-i\theta}} = \dfrac{e^{i\theta}}{e^{i\theta}} \dfrac{1 + e^{i\theta}}{1 + e^{-i\theta}}$ $= e^{i\theta} \dfrac{1 + e^{i\theta}}{e^{i\theta} + 1} = e^{i\theta} = z, \tag{17}$

stipulating of course that $\theta$ is not an odd multiple of $\pi$.

Robert Lewis
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