Mathematical Methods for Physics and Engineering : A Comprehensive Guide

(Darren Dugan) #1

11.6 VOLUME INTEGRALS


V


O


S


r

dS

Figure 11.9 A general volumeVcontaining the origin and bounded by the
closed surfaceS.

cannot be taken out of the integral sign as in (11.13) and must be included as


part of the integrand.


11.6.1 Volumes of three-dimensional regions

As discussed in chapter 6, the volume of a three-dimensional regionVis simply


V=



VdV, which may be evaluated directly once the limits of integration have
been found. However, the volume of the region obviously depends only on the


surfaceSthat bounds it. We should therefore be able to express the volumeV


in terms of a surface integral overS. This is indeed possible, and the appropriate


expression may derived as follows. Referring to figure 11.9, let us suppose that


the originOis contained withinV. The volume of the small shaded cone is


dV=^13 r·dS; the total volume of the region is thus given by


V=

1
3


S

r·dS.

It may be shown that this expression is valid even whenOis not contained inV.


Although this surface integral form is available, in practice it is usually simpler


to evaluate the volume integral directly.


Find the volume enclosed between a sphere of radiusacentred on the origin and a circular
cone of half-angleαwith its vertex at the origin.

The element of vector areadSon the surface of the sphere is given in spherical polar
coordinates bya^2 sinθdθdφˆr. Now taking the axis of the cone to lie along thez-axis (from
whichθis measured) the required volume is given by


V=


1


3



S

r·dS=

1


3


∫ 2 π

0


∫α

0

a^2 sinθr·ˆrdθ

=


1


3


∫ 2 π

0


∫α

0

a^3 sinθdθ=

2 πa^3
3

(1−cosα).
Free download pdf