66 4. INJECTIVITY CRITERIAThen f is analytic in B(O, r) with u =Re(!) and differentiation yields
j'(O) = .!_ (2n u(reie) de=.!_ (2n u(reie) ~ u(O) de.
7r lo re•^8 7r lo re•^8
Since !grad u(O)I = IJ'(O)I, we havelgrad u(O)I::::; .!_ f
2
1r r-^1 lu(rei^8 ) - u(O)I de.
7r lo
From this together with inequality (3.2.1)
lgrad u(O)I PD(o)-^1 ::::; lgrad u(O)l 2d::::; m(~o) fod !grad u(O)l 7rr^2 dr
::::; m(~o) l
0lu(z) - u(O)I dm.Next for (4.3.5) let 'Y be the hyperbolic geodesic joining 0 to z in D. Thenlu(z) - u(O)I ::::; c 1 poi dz I = c hD(z, 0),
whereandc =sup lgrad u(z)I PD(z)-^1
zEDm(~o) l
0lu(z) - u(O)ldm::::; m(~o) lo hD(z, 0) dm::::; 2c
by Lemma 4.3.2. DCOROLLARY 4.3.6 (Astala-Gehring [14]). If f is analytic with J' =/= 0 in D c
R^2 , then
1 1- II log J1llBMO(D) :S sup IT1(z)I PD(z)- :S 3 II log J1llBMO(D)·
4 zED
PROOF. Let u(z) =log lf'(z)I. Then u is harmonic in D,
lf"(z)I
log JJ(z) = 2 log lf'(z)I = 2u(z), ITt(z)I = lf'(z)I =!grad u(z)I,
and the desired conclusion follows from Lemma 4.3.3. D
Corollary 4.3.6 shows that the BMO-norm of log J 1 is a natural alternative
for the pre-Schwarzian derivative Tt when considering injectivity results for locally
conformal mappings. Moreover the following quasiconformal counterpart of The-
orem 4.1.3 and Theorem 4.1.11 suggests that this norm offers a way to extend
results on the injectivity of analytic functions to the class of locally quasiconformal
mappings.THEOREM 4.3.7 (Reimann [146]). If f is K-quasiconformal in D with J(D) C
R^2 , then
II log JtllBMO(D) ::::; m
where m = m(K) < oo. Moreover, when D = R^2 ,
lim m(K) = 0.
K---71