G-CO Inscribing a hexagon in a circle

Since a regular hexagon divides the circle into six equal parts and there are \(360\) degrees in the circle, each side of the regular hexagon should span a chord of \(60\) degrees on the circle. A triangle with vertex \(O\) and its other two vertices on the circle \(C\) is an isosceles triangle since all radii of \(C\) have the same length. So if the angle at \(O\) measures \(60\) degrees, the two base angles must also measure \(60\) degrees making it an equilateral triangle. In order to construct our hexagon, we can start with segment \(OP\) and successively build equilateral triangles from here.

We have \(|PO| = |PQ|\) since both are radii of the circle with center \(P\) and radius \(|OP|\). We also know that \(|PO| = |QO|\) because both are radii of the circle with center \(O\) and radius \(|OP|\). Hence we have $$ |OP| = |PO| = |PQ| $$ and triangle \(OPQ\) is equilateral. The same reasoning applies to triangle \(OPU\).

If we construct a circle with center \(S\) and radius \(|OS|\), as in part (a), we find the following picture:

The reasoning of part (a) applies to show that the two triangles \(ROS\) and \(SOT\) are both equilateral. Now angles \(POQ\), \(QOR\), and \(ROS\) together form a line and so add up to \(180\) degrees. Both \(POQ\) and \(ROS\) have been shown to be \(60\) degree angles and so \(QOR\) is also a \(60\) degree angle. As in part (a), it follows that triangle \(QOR\) is equilateral. The same reasoning applies to show that triangle \(TOU\) is equilateral. We can now conclude that hexagon \(PQRSTU\) is a regular hexagon as each of its six sides is congruent to the radius of circle \(C\).

Hexagon \(PQRSTU\) is made up of six congruent equilateral triangles so we need to find the area of one of these triangles. We will focus on triangle \(OPQ\). Let \(K\) be the midpoint of segment \(OP\):

Triangle \(QKO\) is congruent to triangle \(QKP\) by SSS: \(OQ\) and \(OP\) are radii of congruent circles, \(|QK| = |QK|\) and \(|OK| = |PK|\) since \(K\) is the midpoint of segment \(OP\). Since angles \(OKQ\) and \(PKQ\) are congruent and add up to \(180\) degrees they are right angles. Thus lines \(QK\) and \(OP\) are perpendicular. We have \(|OQ| = r\) since it is a radius of the circle with center \(O\) and radius \(r\). We also have $$ \frac{|OK|}{|OQ|} = \cos{KOQ} $$ and similarly $$ \frac{|QK|}{|OQ|} = \sin{KOQ}. $$ Angle \(KOQ\) measures \(60\) degrees since it is an angle in an equilateral triangle. So we have \(\cos{KOQ} = \frac{1}{2}\) and \(\sin{KOQ} = \frac{\sqrt{3}}{2}\). So we have \(|OK| = \frac{r}{2}\) and \(|QK| = \frac{\sqrt{3}r}{2}\). The area triangle \(QOP\) is the same as the area of a rectangle of width \(|OK|\) and height \(|QK|\) which we have just seen is $$ \frac{\sqrt{3}r^2}{4}. $$ There are six of these equilateral triangles in the hexagon \(PQRSTU\) so the area of this hexagon is $$ \frac{3\sqrt{3}r^2}{2}. $$ This is an area of about \(2.60r^2,\) just under \(83\) percent of the area of the circle.