"Smooth rigidity" and Remez-type inequalities

Abstract

If a function of one variable has maximum one on the unit interval, and has there $d$ zeroes, then its $(d+1)$-st derivative must be big. This is one of the simplest examples of what we call smooth rigidity: certain geometric properties of zero sets of functions $f$ imply explicit lower bounds on the high-order derivatives of $f$. In dimensions greater than one, the powerful one-dimension tools, like Lagrange's remainder formula, and divided finite differences, are not directly applicable. Still, the result above implies, via line sections, rather strong restrictions on zeroes of functions of several variables \cite{Yom1}). In the present paper we study the geometry of zero sets of functions, and significantly extend the results of \cite{Yom1}, including into consideration, in particular, finite zero sets (for which the line sections usually do not work). Our main goal is to develop a truly multi-dimensional approach to rigidity, based on polynomial Remez-type inequalities (which compare the maxima of a polynomial on the unit ball, and on its subset). Very informally, one of our main results is that a smooth rigidity of a zeroes set $Z$ is approximately the inverse Remez constant of $Z$.