1550251515-Classical_Complex_Analysis__Gonzalez_

Differentiation

and since

I( - zl = l(zo -z) + (( -zo)I > r -^1 / 2 r = %r

it follows that

l

f(zo)-f(z) _ f(()-f(z)I <e

Zo - Z (-Z

387

Theorem 6.36 Suppose that f is analytic in a region R and z 0 E R.

Then for any e > 0 there is a 8 > 0 such that

If((~= {(A) - f'(zo)I < e

provided that I( - zol < 8 and IA - zol < 8.

Proof By the definition of the derivative we have

I

f(zo) - f(z) -f'(zo)I < ~e,

Zo -z 2

z ER (6.22-2)

provided that lz -zol $ r, and by Theorem 6.35, there is a 8, 0 < 8 < ~r,

such that

I

f(zo) - f(z) _ f(() - f(z) I< ~e

Zo - Z (-Z 2

(6.22-3)

whenever lz - zol = r and I( - zol < 8. From (6.22-2) and (6.22-3) it

follows that

I

J(() - f(z) - f'(zo)I < e

(-z

For each ( such that I( - zol < 8, define

g (A)= f(()-f(A) (-A if A i= (

and

g(A) = !'(() if A= (

(6.22-4)

for all A with IA - zol $ 8. Then Theorem 6.34 is applicable, and we find,

using (6.22-4),

IY(A) - f'(zo)I $ max I!(()-f(z) - f'(zo)I < e (6.22-5)

lz-zo l=r ( - Z

Theorem 6.37 If f is analytic in a region R, then f' is continuous in R.

Proof For A= ( (6.22-5) reads If'(() - f'(zo)I < e whenever I( - zol < 8.

This expresses the continuity off' at zo. Since zo is an arbitrary point of

R, the theorem holds.