proof of Jordan’s Inequality

To prove that

$\frac{2}{\pi}x\leq\sin(x)\leq x,\forall\;x\in[0,\frac{\pi}{2}]$

consider a circle (circle with radius = 1 ). Take any point $P$ on the circumference of the circle.

Drop the perpendicular from $P$ to the horizontal line, $M$ being the foot of the perpendicular and $Q$ the reflection of $P$ at $M$ . (refer to figure)

Let $x=\angle POM.$

For $x$ to be in $[0,\frac{\pi}{2}]$ , the point $P$ lies in the first quadrant, as shown.

The length of line segment $P M$ is $\sin(x)$ . Construct a circle of radius $M P$ , with $M$ as the center.

Length of line segment $P Q$ is $2\sin(x)$ .

Length of arc $P A Q$ is $2x$ .

Length of arc $P B Q$ is $\pi\sin(x)$ .

Since $PQ\leq$ length of arc $P A Q$ (equality holds when $x=0$ ) we have $2\sin(x)\leq 2x$ . This implies

$\sin(x)\leq x$

Since length of arc $P A Q$ is $\leq$ length of arc $P B Q$ (equality holds true when $x=0$ or $x=\frac{\pi}{2}$ ), we have $2x\leq\pi\sin(x)$ . This implies

$\frac{2}{\pi}x\leq\sin(x)$

Thus we have

$\frac{2}{\pi}x\leq\sin(x)\leq x,\forall\;x\in[0,\frac{\pi}{2}]$

Title	proof of Jordan’s Inequality
Canonical name	ProofOfJordansInequality
Date of creation	2013-03-22 13:08:48
Last modified on	2013-03-22 13:08:48
Owner	mathcam (2727)
Last modified by	mathcam (2727)
Numerical id	17
Author	mathcam (2727)
Entry type	Proof
Classification	msc 26D05