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Volume Integrals

A volume integral takes the form
\begin{displaymath}
\int\!\int\!\int_V f(x,y,z)\,dV,
\end{displaymath} (1341)

where $V$ is some volume, and $dV = dx \,dy \,dz$ is a small volume element. The volume element is sometimes written $d^3{\bf r}$, or even $d\tau$.

As an example of a volume integral, let us evaluate the center of gravity of a solid pyramid. Suppose that the pyramid has a square base of side $a$, a height $a$, and is composed of material of uniform density. Let the centroid of the base lie at the origin, and let the apex lie at $(0,\,0,\,a)$. By symmetry, the center of mass lies on the line joining the centroid to the apex. In fact, the height of the center of mass is given by

\begin{displaymath}
\overline{z} = \left. \int\!\int\!\int z\,dV\right/ \int\!\int\!\int dV.
\end{displaymath} (1342)

The bottom integral is just the volume of the pyramid, and can be written
$\displaystyle \int\!\int\!\int dV$ $\textstyle =$ $\displaystyle \int_0^a dz \int_{-(a-z)/2}^{(a-z)/2} dy\int_{-(a-z)/2}^{(a-z)/2} dx = \int_0^a (a-z)^2\,dz=\int_0^a (a^2-2\,a\,z+z^2)\,dz$  
  $\textstyle =$ $\displaystyle \left[a^2\,z-a\,z^2+z^3/3\right]_0^a= \frac{1}{3}\,a^3.$ (1343)

Here, we have evaluated the $z$-integral last because the limits of the $x$- and $y$- integrals are $z$-dependent. The top integral takes the form
$\displaystyle \int\!\int\!\int z\,dV$ $\textstyle =$ $\displaystyle \int_0^a z\,dz \int_{-(a-z)/2}^{(a-z)/2} dy\int_{-(a-z)/2}^{(a-z)/2} dx = \int_0^a z\,(a-z)^2\,dz=\int_0^a (z\,a^2-2\,a\,z^2+z^3)\,dz$  
  $\textstyle =$ $\displaystyle \left[a^2\,z^2/2-2\,a\,z^3/3+z^4/4\right]_0^a= \frac{1}{12}\,a^4.$ (1344)

Thus,
\begin{displaymath}
\bar{z} = \left.\frac{1}{12}\,a^4\right/\frac{1}{3}\,a^3 = \frac{1}{4}\,a.
\end{displaymath} (1345)

In other words, the center of mass of a pyramid lies one quarter of the way between the centroid of the base and the apex.


next up previous
Next: Gradient Up: Vector Algebra and Vector Previous: Vector Line Integrals
Richard Fitzpatrick 2011-03-31