3.8. HARMONIC QUASISYMMETRY 45for j = 1, 2, 3 and we obtain
1 ¢
w(l,11;D) = -(arctana~ - arctanaf) = -,
n n
1 ¢
w(l,12;D) = -(arctana~ - arctana~) = -
n n
from (3.7.2) and the conformal invariance of harmonic measure. A similar argument
yields1
w(-l, 11; D*) = -(arctan a~ - arctan ai),
n
w(-l,12;D*) = ~(arctanaj-arctana~)
n
and we conclude thatwhere(3.8.6)w(-l,12;D*)
w(-l,11;D*)g(e, t) = arctan(tant e)9 (e + ¢, t) - 9 (e, t)
9 (e, t) - 9 (e - ¢, t)and t= <]_= __ a_.
p 2n-aA technical but elementary argument then shows that1 9 (e+¢,t)- 9 (e,t)
- < < 1
c - 9 (e,t)- 9 (e-¢,t) -
for 0 :::; e -¢ < e + ¢ :::; n /2 and this yields the desired conclusion if /1 and /2
lie on the same ray of 8D. The general conclusion can now be deduced from this
special case.The preceding example suggests the following quasisymmetry property. See
Krzyz [105].DEFINITION 3.8.7. A Jordan domain Dis quasisymmetric if there exist points
z 0 E D , z 0 E D* and a constant c 2: 1 such that if 11 , 12 are adjacent arcs in 8D
with
then
THEOREM 3.8.8 (Krzyz [105]). A Jordan domain D is a K -quasidisk if and
only if it is quasisymmetric with constant c, where K and c depend only on each
other.This result will follow from the discussion in Section 3.12 where it is proved that
a domain is quasisymmetric if and only if it satisfies the conjugate quadrilateral
inequality. See Definition 3.10.8 below.