Equivalence of Definitions of Sine of Angle

Theorem
Let $\theta$ be an angle.

Definition from Triangle implies Definition from Circle
Let $\sin \theta$ be defined as $\dfrac {\text{Opposite}} {\text{Hypotenuse}}$ in a right triangle.

Consider the triangle $\triangle OAP$.

By construction, $\angle OAP$ is a right angle.

Thus:

That is:
 * $\sin \theta = AP$

Definition from Circle implies Definition from Triangle
Let $\sin \theta$ be defined as the length of $AP$ in the triangle $\triangle OAP$.

Compare $\triangle OAP$ with $\triangle ABC$ in the diagram above.

We have that:
 * $\angle CAB = \angle POA = \theta$
 * $\angle ABC = \angle OAP$ which is a right angle

Therefore by Triangles with Two Equal Angles are Similar it follows that $\triangle OAP$ and $\triangle ABC$ are similar.

By definition of similarity:

That is:
 * $\dfrac {\text{Opposite} } {\text{Hypotenuse} } = \sin \theta$

Definition from Circle equivalent to Definition from Real Numbers
Let, $\sin_G$ be the Geometric Sine from Definition:Sine/Definition from Circle. $\arcsin_G$ is the inverse of this function.

Let $sin_A$ be the analytic sine function for real numbers, the one defined by Definition:Sine/Real Numbers. $\arcsin_A$ is the inverse of this function.

We know from Arcsin as an Integral that $\arcsin_A$ and $\arcsin_G$ are the same function.

$x=\sin_A\left({\theta}\right) \iff \arcsin_A\left(x\right)=\theta \iff \arcsin_G\left(x\right)=\theta \iff x=\sin_G\left({\theta}\right)$