Proving $1 \geq \frac{\sin(\theta)}{\theta} \geq \frac{2}{\pi}$ for $\theta \in [0,\frac{\pi}{2}]$

Question

In proving Jordan's lemma, the inequality $$1 \geq \frac{\sin(\theta)}{\theta} \geq \frac{2}{\pi}$$ is used, for $\theta \in [0,\frac{\pi}{2}]$.

I got as far as establishing $1 \geq \sin(\theta) \geq 0$ and $\theta^{-1} \in [\frac{2}{\pi}, \infty)$.

I'm looking for a modest hint.

Answer 1

Modest hint: use convexity (actually, here, concavity) of the function $\sin$ on $[0,\frac{\pi}{2}]$.

Followup hint: (place your mouse on the hidden text to reveal it)

A concave function is below its tangents and above its "secants" (linear functions obtained by joining two points of its graph).

Followup hint: (place your mouse on the hidden text to reveal it)

By concavity, $\sin x \leq \sin 0 + \sin'(0)x$ (tangent at $0$) and $\sin x \geq \frac{2}{\pi}$ (line joining $(0,\sin 0)$ and $(\frac{\pi}{2}, \sin \frac{\pi}{2}$).

Here is an illustration showing the three graphs ($x\mapsto x$, $x\mapsto \sin x$, $x\mapsto \frac{2}{\pi}x$):