Generalized Remez Inequality for (s,p)-Valent Functions

The classical Remez inequality bounds the maximum of the absolute value of a polynomial $P(x)$ of degree $d$ on $[-1,1]$ through the maximum of its absolute value on any subset $Z$ of positive measure in $[-1,1]$. It was shown in \cite{Yom3} that the Lebesgue measure in the Remez inequality can be replaced by a certain geometric invariant $\omega_d(Z)$ which can be effectively estimated in terms of the metric entropy of $Z$ and which may be nonzero for discrete and even finite sets $Z$. In the present paper we first obtain an essentially sharp Remez-type inequality in the spirit of \cite{Yom3} for complex polynomials of one variable, introducing metric invariants $c_d(Z)$ and $\o_{cd}(Z)$ for an arbitrary subset $Z\subset D_1\subset {\mathbb C}$. These invariants translate into the the metric language the classical Cartan lemma (see \cite{Gor} and references therein). Next we introduce $(s,p)$-valent functions, which provide a natural generalization of $p$-valent ones (see \cite{Hay} and references therein). We prove a "distortion theorem" for such functions, comparing them with polynomials sharing their zeroes. On this base we extend to $(s,p)$-valent functions our polynomial Remez-type inequality. As the main example we consider restrictions $g$ of polynomials of a growing degree to a fixed algebraic curve, for which we obtain an essentially sharp "local" Remez-type inequality, stressing the role of the geometry of singularities of $g$. Finally, we obtain for such functions $g$ a "global" Remez-type inequality which is valid for all the branches of $g$ and involves both the geometry of singularities of $g$ and its monodromy.