Lesson 11

Calculate the area of the shaded regions.

The applet shows a regular \(n\)-sided polygon inscribed in a circle. 

Come up with a general formula for the perimeter of the polygon in terms of \(n\).  Explain or show your reasoning.

Let's use the expression you came up with to approximate the value of \(\pi\).

1. How close is the approximation when \(n=6\)?
2. How close is the approximation when \(n=10\)?
3. How close is the approximation when \(n=20\)?
4. How close is the approximation when \(n=50\)?
5. What value of \(n\) approximates the value of \(\pi\) to the thousandths place?

It's easier to work with polygons than with circles because we can decompose polygons into simple shapes such as triangles. We can use polygons to figure out things about circles. For example, we know how to calculate the area of regular polygons inscribed in a circle of radius 1.

To find the area of this regular pentagon, let's find the area of one triangle and then multiply by 5. Drawing in the altitude creates a right triangle, so we can use trigonometry to calculate the lengths of both \(x\) and \(h\). To find \(\theta\) use the fact that a full rotation is \(360^\circ\) and that in an isosceles triangle the altitude is also an angle bisector. So \(\theta=360 \div 10\). \(\sin(36)=\frac{x}{1}\) so \(x\) is about 0.59 units. \(\cos(36)=\frac{h}{1}\) so \(h\) is about 0.81 units. The area of the isosceles triangle is about 0.48 square units and the area of the pentagon is 5 times that, or about 2.4 square units.

That's not very close to the area of the circle, but if we add more and more sides to the regular polygon, its area gets closer and closer to covering the entire circle.