Chapter 3 1. Line Integral Volume Integral Surface Integral Green’s Theorem Divergence Theorem (Gauss’ Theorem) Stokes’ Theorem
Example (Volume Integral) z y 4 3
Solution Since it is about a cylinder, it is easier if we use cylindrical polar coordinates, where
Line Integral Ordinary integral f (x) dx, we integrate along the x-axis. But for line integral, the integration is along a curve. f (s) ds = f (x, y, z) ds A O B
Scalar Field, V Integral If there exists a scalar field V along a curve C, then the line integral of V along C is defined by
Example
Solution
Exercise 2.6
2.8.2 Vector Field, Integral Let a vector field and The scalar product is written as
Example 2.15
Solution
Exercise 2.7
* Double Integral *
2.9 Volume Integral 2.9.1 Scalar Field, F Integral If V is a closed region and F is a scalar field in region V, volume integral F of V is
Example 2.20 Scalar function F = 2 x defeated in one cubic that has been built by planes x = 0, x = 1, y = 0, y = 3, z = 0 and z = 2. Evaluate volume integral F of the cubic. z x y 3 O 2 1
Solution
2.9.2 Vector Field, Integral If V is a closed region and , vector field in region V, Volume integral of V is
Example 2.21 Evaluate , where V is a region bounded by x = 0, y = 0, z = 0 and 2x + y + z = 2, and also given
Solution If x = y = 0, plane 2x + y + z = 2 intersects z-axis at z = 2. (0,0,2) If x = z = 0, plane 2x + y + z = 2 intersects y-axis at y = 2. (0,2,0) If y = z = 0, plane 2x + y + z = 2 intersects x-axis at x = 1. (1,0,0)
z y x We can generate this integral in 3 steps : 2 O 1 2x + y + z = 2 y = 2 (1 x) We can generate this integral in 3 steps : Line Integral from x = 0 to x = 1. Surface Integral from line y = 0 to line y = 2(1-x). Volume Integral from surface z = 0 to surface 2x + y + z = 2 that is z = 2 (1-x) - y
Therefore,
Example 2.22 Evaluate where and V is region bounded by z = 0, z = 4 and x2 + y2 = 9 x z y 4 3
Using polar coordinate of cylinder, ; ; ; where
Therefore,
Exercise 2.8
2.10 Surface Integral 2.10.1 Scalar Field, V Integral If scalar field V exists on surface S, surface integral V of S is defined by where
Example 2.23 Scalar field V = x y z defeated on the surface S : x2 + y2 = 4 between z = 0 and z = 3 in the first octant. Evaluate Solution Given S : x2 + y2 = 4 , so grad S is
Also, Therefore, Then,
Surface S : x2 + y2 = 4 is bounded by z = 0 and z = 3 that is a cylinder with z-axis as a cylinder axes and radius, So, we will use polar coordinate of cylinder to find the surface integral. x z y 2 3 O
Polar Coordinate for Cylinder where (1st octant) and
Using polar coordinate of cylinder, From
Therefore,
Exercise 2.9
2.10.2 Vector Field, Integral If vector field defeated on surface S, surface integral of S is defined as
Example 2.24
Solution x z y 3 O
Using polar coordinate of sphere,
Exercise 2.9
2.11 Green’s Theorem If c is a closed curve in counter-clockwise on plane-xy, and given two functions P(x, y) and Q(x, y), where S is the area of c.
Example 2.25 y 2 x C3 C2 C1 O x2 + y2 = 22 Solution
2.12 Divergence Theorem (Gauss’ Theorem) If S is a closed surface including region V in vector field
Example 2.26
Solution x z y 2 4 O S3 S4 S2 S1 S5
2.13 Stokes’ Theorem If is a vector field on an open surface S and boundary of surface S is a closed curve c, therefore
Example 2.27 Surface S is the combination of
Solution z y x 3 4 O S3 C2 S2 C1 S1
We can also mark the pieces of curve C as C1 : Perimeter of a half circle with radius 3. C2 : Straight line from (-3,0,0) to (3,0,0). Let say, we choose to evaluate first. Given
So,
By integrating each part of the surface,
Then , and
By using polar coordinate of cylinder ( because is a part of the cylinder),
Therefore, Also,
(ii) For surface , normal vector unit to the surface is By using polar coordinate of plane ,
For surface S3 : y = 0, normal vector unit to the surface is dS = dxdz The integration limits : So,