Area, Volume, and Arc Length Exercises

Answer

This is very similar to the example. We slice the pyramid horizontally and get a slice that's a square:

We cut the pyramid in half from top to bottom to see the similar triangles. Since h is the distance from the base of the pyramid to the slice, h is no longer the height of the smaller triangle. The height of the smaller triangle is now

(9 – h). If we let x be the length of the side of the slice, we get

so

The area of the square is

so the volume of the slice is

The volume of the entire pyramid is

Answer

This problem is like the example except that we don't have numbers anymore. We just have letters. Good grief. Since h is being used as the height of the pyramid, let's use y for the distance from the top of the pyramid to a slice. We will use y as the distance from the top of the pyramid to the slice, rather than the bottom of the pyramid to the slice. It makes the similar triangle ratios nicer. We cut the pyramid down the middle to see the similar triangles. Letting x be the length of the side of the square, we have

so

The area of the square is

and the volume of the slice is

The volume of the pyramid is

Let's evaluate the integral. Remember that b and h are constants, so we can move them outside of the integral:

Answer

We slice the cone horizontally. The slices are circular with thickness Δ h.

When we cut the cone down the center to look at the similar triangles, we notice that the height of the smaller triangle is (5 – h), not h, since we're measuring from the tip.

Using the similar triangles and letting x be the radius of the slice, we have

so

The area of the circle is

and the volume of the slice is

The volume of the entire cone is

Answer

This is just like the example except there aren't any numbers. Since h is being used for the height of the cone, let's use y for the distance from the tip of the cone to the slice. Then the thickness of the slice is Δ y. We cut the cone down the middle to see the similar triangles, and mark the radius of the slice as x. Using similar triangles,

so

The circular side of the slice has area

and the slice has volume

Since the variable y goes from 0 (at the tip of the cone) to h (at the base of the cone), the volume of the cone is

Let's work out the integral. Remember that r, h, and π are constants so we can pull them out of the integral if need be.

Look forward? It should. That's the formula for the volume of a cone.

Answer

We'll start by slicing the sphere horizontally, then we'll mark h as the depth of the slice below the top of the sphere. Each slice has thickness Δ h.

If we cut the sphere in half along the xz-plane we can see half the sphere and half the slice. The radius of the slice is x where x² + z² = 4². Notice that z = 4 – h.

Since z = 4 – h, the Pythagorean Theorem says

x² + (4 – h)² = 4²

so

This means the area of the circular side of the slice is

The volume of a slice is

π(4²– (4 – h)²) Δ h,

and the volume of the sphere is

We can simplify this integral using the sphere's symmetry to

We could solve either integral, but it's up to you to solve the one that's easiest. We recommend the second one.

Answer

This is like the example but with no numbers. Yes, there's a theme here. We told you we would give you the power to derive any area formula you wanted. We'll slice the sphere vertically and use x to denote the position of a slice. Each slice has thickness Δ x. If we cut the sphere down the middle we can see the radius of the slice is z where x² + z² = r². This means  so the area of the circle is

and the volume of the slice is

π(r² – x²) Δ x.

The volume of the sphere is

or

We'll evaluate the second integral. Drats. Karma finally caught up.

There it is—our nice, familiar formula for the volume of a sphere.