10 .4. APOLLONIAN METRIC IN A QUASIDISK 147by (10.4.15). Hence m < r/2. Next
C = 8D C {z: r - 1 ::=::: lz l ::=::: r + l}.
and by performing a preliminary rotation, we m ay assume that{arg(z): z E R^2 } = [-¢,¢]
where¢> 0.
We shall show that ¢ ::::: 7f /6. For t his fix 0 < B < min(¢, 7f /2) and choose
w 1 , w2, w3, w4 E C so that arg(w2) = B, arg(w4) = -B and so that w1 and W3 are
positive and separate w 2 , w 4 in C. Then w 1 , w 2 , W3, w 4 is an ordered quadruple of
points on the K-quasicircle C with
Hence
r sin(B) ::=:::min ( lw2 - r l, lw4 - rl)::::: m < r/2
by Corollary 10.4.12 and B < 7f /6. Thus ¢ ::::: 7f /6 and
CC {z: r - 1 ::=::: lz l ::=::: r + 1, I arg(z)I ::=::: 7r/6}.
Let U denote the smallest closed disk with center on { z : lz l = r} which contains
C; by performing a second preliminary rotation we may assume that
U={z: lz-rl:=::b}.
Then b ::=::: m, for if b > 1, there exists as above an ordered quadruple of points
w1, w2, w3, W4 on C such that
max(lw1 - rl, lw3 - rl)::::: 1 < b = lw2 - rl = lw4 - rl
and b::::: m by Corollary 10.4.12.
Finally, set
m
f(z ) = -.
r - z
Then BC f(D) and
(
hD(O, oo) = hf(D)(m/r, 0) ::=::: hB(m/r, 0) =log --r+m).
r-mHence if
g(t) =log G ~:) -m
2
log G ~ ~),then g'(t) > 0 for r < t < oo and we obtain
m^2 aD(O, oo) - hD(O, oo) 2: lim (g(s) - g(r)) = j
00
g'(t) dt > 0.
s -tc:>O rCOROLLARY 10.4.17. If DC R^2 is a K-quasidisk, then
(10.4.18)
for z1, z2 ED where c(K)---+ 1 as K---+ 1.D