This problem is driving me crazy. It's from Andreescu's Mathematical Olympiad Challenges:
Let $AB$ be a chord in a circle and $P$ a point on the circle. Let $Q$ be the projection of $P$ onto $AB$ and $R$ and $S$ the projections of $P$ onto the tangents to the circle at $A$ and $B$. Prove that $PQ$ is the geometric mean of $PR$ and $PS$.
The solution given is as follows:
We will prove that the triangles $PRQ$ and $PQS$ are similar. This will imply $PR/PQ = PQ/PS$; hence $PQ^2 = PR\cdot PS$.
The quadrilaterals $PRAQ$ and $PQBS$ are cyclic, since each of them has two opposite right angles. In the first quadrilateral $\angle PRQ=\angle PAQ$ and in the second $\angle PQS = \angle PBS$. By inscribed angles, $\angle PAQ$ and $\angle PBS$ are equal. It follows that $\angle PRQ = \angle PQS$. A similar argument shows that $\angle PQR=\angle PSQ$. This implies that the triangles $PRQ$ and $PQS$ are similar, and the conclusion follows.
Now, just HOW by inscribed angles is $\angle PAQ=\angle PBS$? Those two do not subtend chords in the same circle, and I tried using angle chasing to find their values, but even if I consider the larger cyclic quadrilateral with vertices $P,R,S$ and the intersection of the tangents of $A$ and $B$, the two don't subtend any chords in common.
Can someone enlighten this tortured soul? I've been chasing angles for the past month now and it even haunts my dreams.
In many countries "inscribed angles" subsumes a group of theorems, including
It is the last point which is relevant for this step.
You can find it at the end of the wikipedia article as a "corollary": http://en.wikipedia.org/wiki/Inscribed_angle
There are many proofs possible, but you might want to use the fact that the endpoints of the chord, the center of the circle and the intersection of the two tangents also form a cyclic quadrilateral and the ordinary inscribed angle theorem gives the desired relation.