MULTIPLE INTEGRALS
yxu=constant
v=constantN
M
L
K
R
C
Figure 6.10 A region of integrationRoverlaid with a grid formed by the
family of curvesu=constantandv= constant. The parallelogramKLMN
defines the area elementdAuv.express a multiple integral in terms of a new set of variables. We now consider
how to do this.
6.4.1 Change of variables in double integralsLet us begin by examining the change of variables in a double integral. Suppose
that we require to change an integral
I=∫∫Rf(x, y)dx dy,in terms of coordinatesxandy, into one expressed in new coordinatesuandv,
given in terms ofxandyby differentiable equationsu=u(x, y)andv=v(x, y)
with inversesx=x(u, v)andy=y(u, v). The regionRin thexy-plane and the
curveCthat bounds it will become a new regionR′and a new boundaryC′in
theuv-plane, and so we must change the limits of integration accordingly. Also,
the functionf(x, y) becomes a new functiong(u, v) of the new coordinates.
Now the part of the integral that requires most consideration is the area element.In thexy-plane the element is the rectangular areadAxy=dx dygenerated by
constructing a grid of straight lines parallel to thex-andy- axes respectively.
Our task is to determine the corresponding area element in theuv-coordinates. In
general the corresponding elementdAuvwill not be the same shape asdAxy, but
this does not matter since all elements are infinitesimally small and the value of
the integrand is considered constant over them. Since the sides of the area element
are infinitesimal,dAuvwill in general have the shape of a parallelogram. We can
find the connection betweendAxyanddAuvby considering the grid formed by the
family of curvesu=constantandv= constant, as shown in figure 6.10. Sincev