11.3. HOMOGENEITY AND QUASIDISKSsince by monotonicityBut by (11.1.6)andso thatThis means thatw(z, f)D,* n &G; G) 2: w(z, 1; D*).w(z,S;D*) _::; ~
1T d(z, S)4
1 - r:iT::C\ :::; w(z, &D* n &G; G) _::; c < 1
7Ty d(z, S)lzi -zJ - 1 :S: d(z, S) _::; ( 7r(l ~ c))
2
+ 1.153011.2. Quasidisks and quasiconformal extension domains
THEOREM 11.2.1. If D is a K-quasidisk, then any K' -quasiconformal self-
mapping f of D has a cK' -quasiconformal extension as a self-mapping ofR
2
, where
c only depends on K.PROOF. We may assume that D = g(B) for a K-quasiconformal mapping g of
R2. Then the mapping h = g-^1 of o g is a K^2 K'-quasiconformal self-mapping of
B and thus h as a K^2 K'-quasiconformal extension to R
2
by Example 5.3.2. Then
the mapping go h o g-^1 is a K^4 K'-quasiconformal extension of g, so we may take
c = K^4. D
Thus quasidisks are quasiconformal extension domains.
Next we prove that quasiconformal extension domains are homogeneous with
respect to the family of mapping QC.
THEOREM 11.2.2. If a simply connected domain D is a quasiconformal exten-
sion domain with constant c, then it is homogeneous with respect to QC ( c).PROOF. For this, fix z 1 , z2 ED, let f be a co nformal mapping of D onto B , and
let Wj = f(zj ) for j = 1, 2. Then there exists a Mobius transformation g: B-+ B
such that g(wi) = w2 and hen ce h = 1-^1 o go f is a conformal se lf-mapping of D
which maps z 1 onto z2. Then since Dis a quasiconformal extension domain, h has
a c-quasiconform al extension to R2
, and t hus D is homogeneous. 011.3. Homogeneity and quasidisks
We will give a proof due to Sarvas [153] for the case when the homogeneity
is with respect to quasiconformal maps of the domain. The argument is a clever
application of the three-point condition for quasidisks. See Theorem 2.2.5.
THEOREM 11.3.1. A Jordan domain D is a quasidisk if it is homogeneous with
respect to the family QC(K) for some fixed K.