If we make the wrong choice, the computations can get quite messy. The decision of which way to slice the solid is very important. As we see later in the chapter, there may be times when we want to slice the solid in some other direction-say, with slices perpendicular to the y-axis. We want to divide S S into slices perpendicular to the x -axis. įigure 6.12 A solid with a varying cross-section. In the case of a right circular cylinder (soup can), this becomes V = π r 2 h. To calculate the volume of a cylinder, then, we simply multiply the area of the cross-section by the height of the cylinder: V = A The solid shown in Figure 6.11 is an example of a cylinder with a noncircular base. Thus, all cross-sections perpendicular to the axis of a cylinder are identical. A cylinder is defined as any solid that can be generated by translating a plane region along a line perpendicular to the region, called the axis of the cylinder. We define the cross-section of a solid to be the intersection of a plane with the solid. To discuss cylinders in this more general context, we first need to define some vocabulary. Although most of us think of a cylinder as having a circular base, such as a soup can or a metal rod, in mathematics the word cylinder has a more general meaning. We can also calculate the volume of a cylinder. Although some of these formulas were derived using geometry alone, all these formulas can be obtained by using integration. The formulas for the volume of a sphere ( V = 4 3 π r 3 ), ( V = 4 3 π r 3 ), a cone ( V = 1 3 π r 2 h ), ( V = 1 3 π r 2 h ), and a pyramid ( V = 1 3 A h ) ( V = 1 3 A h ) have also been introduced. The volume of a rectangular solid, for example, can be computed by multiplying length, width, and height: V = l w h. Most of us have computed volumes of solids by using basic geometric formulas. Just as area is the numerical measure of a two-dimensional region, volume is the numerical measure of a three-dimensional solid. We consider three approaches-slicing, disks, and washers-for finding these volumes, depending on the characteristics of the solid. In this section, we use definite integrals to find volumes of three-dimensional solids. In the preceding section, we used definite integrals to find the area between two curves. 6.2.3 Find the volume of a solid of revolution with a cavity using the washer method.6.2.2 Find the volume of a solid of revolution using the disk method.6.2.1 Determine the volume of a solid by integrating a cross-section (the slicing method).
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