Try splitting up \sin(1-x) using the difference formula for \sin - \sin(\alpha \pm \beta) = \sin \alpha \cos \beta \pm \cos \alpha \sin \beta \! This should tell you what your particular ...

Because you are always evaluating the limit, this is an asymptotic expansion of the explicit expression for the solutions. Write x=2\pi n +\epsilon You get \sin \epsilon=\frac{1}{2\pi n +\epsilon} ...

Let’s just solve the general \sin x = t and later set t=8. e^{ix}= \cos x + i \sin x e^{-ix} = \cos x - i \sin x e^{ix} - e^{-ix} = 2i \sin x \sin x = \dfrac{e^{ix} - e^{-ix}}{2i} ...

You're essentially there: y = x + \cos(x) = \frac\pi2 + 2\pi k + \cos(\frac\pi2 + 2\pi k) = \frac\pi2 + 2\pi k. There are infinitely many y-values, one for each k \in \mathbb{Z}.

From 2 \sin x=1, you should have \sin x=0.5. Sine is positive in the first two quadrants, you should obtain 30^{\circ} and 150^{\circ} as your solution as well.

YOU are right. I cannot find any errors.