Singularities/Residues/ Applicationsand letf(z) = zn, g(z) = a1zn-l +···+an
Choose a circle C: lzl = R such thatR >. max(l, ia1 I+···+ iani)
Then on iz I = R we havelf(z)i = lzln =Rn···-
747lg(z)i::; ia1IRn-l + ... + ianl < Rn-l(la1i + "' + iani) <Rn
so thatlg(z)I < lf(z)I
on lzl = R. It follows that f + g has inside C as many roots as f(z) = zn,
namely, n. Clearly, f + g has no roots for izl 2: R.
- To show that the equation ez - 3z = 0 has just one zero inside lzl = 1.
Let f(z) = -3z and g(z) = ez. On lzl = 1 we have
lf(z)I = 3lzl = 3, lg(z)I = e"'::; e < 3
Hence lg(z)I < lf(z)I for lzl = 1, so that ez - 3z has as many zeros as
f(z) = -3z inside izl = 1, namely, one zero.
Theorem 9.22 (Hurwitz's Theorem). Let Un(z)}~ be a sequence of
analytic functions in some open set A, and suppose that:
- fn(z) ~ f(z) on every compact subset of A.
- J(z) is not identically zero in A.
Then a point z 0 E A, z 0 -=/=-oo, is a zero of f(z) if either (1) z 0 is a zero
of each fn(z) for n large enough, or (2) z 0 is an accumulation point of the
set of zeros or the fn(z).
Proof By Theorem 8.2 the function f(z) is analytic in A. Let 'Y be a circle
around zo contained in A and such that f(z) does not vanish on or inside
"f, except possibly at zo. Since f is continuous on 'Y and f(z)-=/=-0 for z E /,
there exists c > 0 such that
lf(z)I 2: c (9.15-8)
for all z E 'Y· Also, since fn(z) ~ f(z) on compact subsets, we have
lfn(z) - f(z)I < c (9.15-9)