By Euler's identity, $$e^{i\theta}=\cos\theta+i\sin\theta$$ And so if we let $$\phi=e^{i\theta}=\cos\theta+i\sin\theta$$ Then we have $$\phi=e^{i\theta}$$ $$\theta=\frac{\ln\phi}{i}$$ $$\theta=-i\ln\phi$$ and $$\phi=\cos\theta+i\sin\theta$$ and, using an inversion formula that I explained in my question here, $$\theta=\arcsin\frac{\phi}{\sqrt{1^2+i^2}}-\arcsin\frac{1}{\sqrt{1^2+i^2}}$$ $$\theta=\arcsin\frac{\phi}{\sqrt{1-1}}-\arcsin\frac{1}{\sqrt{1-1}}$$ $$\theta=\arcsin\frac{\phi}{0}-\arcsin\frac{1}{0}$$ and so it seems that $$-i\ln\phi=\arcsin\frac{\phi}{0}-\arcsin\frac{1}{0}$$ Is there any meaning in this whatsoever? Why does this happen when I try to manipulate Euler's formula?
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Your problem resides in taking the $\ln$ of a complex exponential. You assert that $e^{i \theta} = \phi$, but notice that:
$$e^{i \tau} = e^{2 i \tau} = e^{3 i \tau} = ... = 1$$
(I use $\tau = 2 \pi$). This shows that the complex exponential is not a one-to-one function, and so you can't just take its inverse with $\ln$. Thus your assertion that:
$$ \theta = \frac{\ln \phi}{i}$$
May not be true.
[EDIT:] In regards to why you obtain a division by zero inside your $\arcsin$, the issue lies in the derivation of your formula for inverting $a \cos x + b \sin x$.
In your question that you referenced, you multiply and divide your equation by $\sqrt{a^2 + b^2}$. In this case, since $a^2 + b^2 = 0$, you're dividing by $0$, which isn't allowed. You may have to find a different way to get an inverse while avoiding dividing by zero.
Sambo
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Okay, fair enough... but even if I find the general solution of $$\phi=\cos\theta+i\sin\theta$$ it will still contain $\frac{\phi}{0}$ and $\frac{1}{0}$. Why does that happen? – Franklin Pezzuti Dyer Jul 26 '17 at 15:26
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Either $\theta=-i\log(\phi)+2\pi k$ for some $k\in\mathbb{Z}$, or, if $\theta\in\mathbb{R}$, $\theta=2\tan^{-1}\left(\frac{\operatorname{Im}(\phi)}{1+\operatorname{Re}(\phi)}\right)$ – robjohn Jul 26 '17 at 16:28