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In 1984 J. Clunie and T. Sheil-Small proved ([2, Corollary 5.8]) that for any complex-valued and sense-preserving injective harmonic mapping F in the unit disk D, if F(D) is a convex domain, then the inequality |G(z2)− G(z1)| < |H(z2) − H(z1)| holds for all distinct points z1, z2∈ D. Here H and G are holomorphic mappings in D determined by F = H + Ḡ, up to a constant function. We extend this inequality by replacing the unit disk by an arbitrary nonempty domain Ω in ℂ and improve it provided F...

Quasihomography is a useful notion to represent a sense-preserving automorphism of the unit circle T which admits a quasiconformal extension to the unit disc. For K ≥ 1 let $A_T\left(K\right)$ denote the family of all K-quasihomographies of T. With any $f\in A_T\left(K\right)$ we associate the Douady-Earle extension $E_f$ and give an explicit and asymptotically sharp estimate of the $L_{\infty }$ norm of the complex dilatation of $E_f$.

In 1984 J. Clunie and T. Sheil-Small proved ([2, Corollary 5.8]) that for any complex-valued and sense-preserving injective harmonic mapping $F$ in the unit disk $𝔻$, if $F\left(𝔻\right)$ is a convex domain, then the inequality $|G\left(z_2\right)-G\left(z_1\right)|<|H\left(z_2\right)-H\left(z_1\right)|$ holds for all distinct points $z_1,z_2\in 𝔻$. Here $H$ and $G$ are holomorphic mappings in $𝔻$ determined by $F=H+\overline{G}$, up to a constant function. We extend this inequality by replacing the unit disk by an arbitrary nonempty domain $\Omega$ in $ℂ$ and improve it provided $F$ is additionally a quasiconformal mapping in $\Omega$.