6.3 APPLICATIONS OF MULTIPLE INTEGRALS
and letN→∞as each of the volumes ∆Vp→0. If the sumStends to a unique
limit,I, then this is called thetriple integral off(x, y, z)over the regionRand is
written
I=∫Rf(x, y, z)dV , (6.5)wheredVstands for the element of volume. By choosing the subregions to be
small cuboids, each of volume ∆V=∆x∆y∆z, and proceeding to the limit, we
canalsowritetheintegralas
I=∫∫∫Rf(x, y, z)dx dy dz, (6.6)where we have written out the element of volume explicitly as the product of the
three coordinate differentials. Extending the notation used for double integrals,
we may write triple integrals as three iterated integrals, for example,
I=∫x 2x 1dx∫y 2 (x)y 1 (x)dy∫z 2 (x,y)z 1 (x,y)dz f(x, y, z),where the limits on each of the integrals describe the values thatx,yandztake
on the boundary of the regionR. As for double integrals, in most cases the order
of integration does not affect the value of the integral.
We can extend these ideas to define multiple integrals of higher dimensionalityin a similar way.
6.3 Applications of multiple integralsMultiple integrals have many uses in the physical sciences, since there are numer-
ous physical quantities which can be written in terms of them. We now discuss a
few of the more common examples.
6.3.1 Areas and volumesMultiple integrals are often used in finding areas and volumes. For example, the
integral
A=∫RdA=∫∫Rdx dyis simply equal to the area of the regionR. Similarly, if we consider the surface
z=f(x, y) in three-dimensional Cartesian coordinates then the volume under this
surface that stands vertically above the regionRis given by the integral
V=∫RzdA=∫∫Rf(x, y)dx dy,where volumes above thexy-plane are counted as positive, and those below as
negative.