Chapter 21
The Integral on Two DimensionalSurfaces In R3
A parametric surface is the image of a vector valued function of two variables. Earlier,vector valued functions of one variable were considered in the study of space curves. Herethere are two independent variables. This is why the result could be expected to be asurface. For example, you could have
r (s, t) =(
x y z)=(
s+ t cos(s)sin(s) ts)
for (s, t) ∈ (0,1)× (0,1). Each value of (s, t) gives a point on this surface. The surfaceis smooth if all the component functions are C1 and rs×rt (s, t) ΜΈ= 0. This last conditionassures the existence of a well defined normal vector to the surface, namely rs×rt (s, t).Recall from the material on space curves that rt ,rs are both tangent to curves which lie inthis surface. If this cross product were 0, you would get points or creases in the surface.
21.1 The Two Dimensional Area In R3
Consider a function defined on a two dimensional surface. Imagine taking the value ofthis function at a point, multiplying this value by the area of an infinitesimal chunk of arealocated at this point and then adding these together. The only difference is that now youneed a two dimensional chunk of area rather than one dimensional.
Definition 21.1.1 Let u1,u2 be vectors in R3. The 2 dimensional parallelogram deter-mined by these vectors will be denoted by P(u1,u2) and it is defined as
P(u1,u2)≡
{2
∑j=1
s ju j : s j ∈ [0,1]
}.
Then the area of this parallelogram is
area P(u1,u2)≡ |u1×u2| .
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