Sharp L1 Poincare inequalities correspond to optimal hypersurface cuts

Abstract

Let ⊂ Rn be a convex. If u: → R has mean 0, then we have the classical Poincar\'e inequality \|u \|Lp ≤ cp diam() \| ∇ u \|Lp with sharp constants c2 = 1/π (Payne \& Weinberger, 1960) and c1 = 1/2 (Acosta \& Duran, 2005) independent of the dimension. The sharp constants cp for 1 < p < 2 have recently been found by Ferone, Nitsch \& Trombetti (2012). The purpose of this short paper is to prove a much stronger inequality in the endpoint L1: we combine results of Cianchi and Kannan, Lov\'asz \& Simonovits to show that \|u\|L1() ≤ 22 M() \|∇ u\|L1() where M() is the average distance between a point in and the center of gravity of . If is a simplex, this yields an improvement by a factor of n in n dimensions. By interpolation, this implies that that for every convex ⊂ Rn and every u: → R with mean 0 \|u\|Lp()≤ (22 M() )1pdiam()1-1p\|∇ u\|Lp().