DifferentiationThen we haveand8zf = fz =^1 Mfx - ify)
az1=fz=^1 /2Ux + ify)fx = fz + Jz, fy = i(fz - fz)
With this new notation, equation (6.7-5) becomes
df = fzdz + f -zdz
We note thatfz = %[(ux + ivx)-i(uy +ivy)]
= %[(ux + vy) + i(vx -Uy)]fz =^1 / 2 [(ux + ivx) + i(uy +ivy)]
=^1 / 2 [(ux - Vy)+ i(vx + uy)]From (6.7-8) and (6.7-9) it follows that
and
'lfzl^2 =^1 / 4 [(ux + vy)^2 + (vx -.uy)^2 ]
lfzl^2 =^1 /4[(ux - vy)^2 + (vx + uy)^2 ]327(6. 7-7)(6.7-8)(6.7-9)(6.7-10)By addition and subtraction of equations (6.7-8) and (6.7-9) we getf z + f z = Ux + ivx
i(fz - fz) =Uy +ivy(6.7-11)
(6.7-12)We make use of (6.7-11) and (6.7-12) in Section 6.10. If f is monogenic at
z, then Ux = Vy and Uy = -Vx and (6.7-9) becomes
fz = 0 (6.7-13)Equation (6.7-13) is to be considered as the complex form of the Cauchy-
Riemann equations.
Let P be a function (or operator) acting on a set S. Then the set
K ={a: a E S,Pa = O} is called the kernel of P .. Equation (6.7-13) shows
that the kernel of the operator 8-z acting on 'D(A) is the family H(A) of
analytic functions in A.
Also, if the equations Ux =Vy, Uy = -vx are satisfied, equation (6.7-8)
becomes
fz = Ux + ivx = f'(z) (6.7-14)