350 Chapter6Fig. 6.7By eliminating the parameter () we obtain the equation of the graph of
the Kasner circle in the form
1(-fzl = lfzl (6.11-2)
or, alternatively, letting ( = e + i17, and taking into account (6.7-8) and
(6.7-9),
[e -%(u,,, + vy)]^2 + [11-^1 Mv,,, -uy)]^2 =^1 / 4 ((u,,, - vy)^2 + (v,,, + uy)^2 ]
Hence the center of the circle is at the point
fz = %[(u,,, + vy) + i(v,,, - uy)]
and its radius is
lf.zl = %.j(u,,, - vy)^2 + (v,,, + uy)2
The Kasner circle reduces to the point fz when f is monogenic at z.
Example Let f(z) = z. Then fz = O, fz = 1, and ( = e-^2 i^6 (0::; ()::; 271').
Thus the Kasner circle is in this case a unit circle with center at the origin
described twice in the clockwise direction (Fig. 6. 7).
EXERCISES 6.2
- (a) F'ind the directional derivative of the function f(z) = z^2 Imz at
·the point z = 1 in the direction () = -^1 / 4 71'.
(b) Determine the point of the complex plane where the function in
part (a) has an ordinary derivative. - (a) Find the directional derivative of the function f ( z) = ( z - 1 )^2 Re z
at the point z = 0 in the direction () = 71' /3.
(b) Determine the points of the complex plane where the function in
part (a) has an ordinary derivative.