502 CHAPTER 11 • APPLICATIONS OF HARMONIC FUNCTIONS
Next, we use the change of variable h = r tan t and dh = r sec^2 t dt and the
· · ·d 't^2 t r2
+ h2
tngonometnc 1 ent1 y sec = b. th. I t. t al
r^2 to o tam e equ1va en 1n egr :
J~(q/2)costr^2 +h^2 qjlf q
IE(x,y)I = 2 f2 dt =
2
cost dt = -.
.::;.r+i r r;;;. 1'
Multiplying this magnitude ~ by the unit vector l: I establishes Formula (11-41).
If q > 0, then the field is directed away from zo = 0 and, if q < 0, then it is
directed toward zo = 0. An electrical field located at zo :/= 0 is given by
E x _ q(z - zo) _ q(,y)- (^1) z-zo 12 - =--=· z -zo
and the corresponding complex potential is
F(z) = -qlog(z-zo).
- EXAMPLE 11 .30 (Source and sink of equal strength) Let a source and sink
of unit strength be located at the points +1 and - 1, respectively. The complex
potential for a fluid ftowing from the source at + 1 to the sink at - 1 is
z-1
F (z) = log(z - 1) - log(z + 1) =log--.
z+l
The velocity potential and stream function arel
z - 11
z+ 1z-l
and 'I/! (x , y) = arg --
1,
z+respectively. Solving for the streamline 'ljJ (x, y) = c, we start withz - 1 x^2 + y^2 - 1 + i2y Zy
c = arg --= arg = arctan ~-"=---
z + 1 (x+l )^2 +y2 x^2 +y^2 - land obtain the equation (tanc) (x^2 + y^2 - 1) = Zy. A straightforward calcula-
tion shows that points on the streamline must satisfy the equat ionx^2 + (y-cotc)^2 = 1 + cot^2 c,
whicli is the equation of a circle with center at (0, cot c) that passes through the
points (±1, 0). Several streamlines are indicated in Figure ll.95(a).