From affine Poincar\'e inequalities to affine spectral inequalities

Abstract

Given a bounded open subset of Rn, we establish the weak closure of the affine ball B Ap() = \f ∈ W1,p0():\ Ep f ≤ 1\ with respect to the affine functional Epf introduced by Lutwak, Yang and Zhang in [43] as well as its compactness in Lp() for any p ≥ 1. These points use strongly the celebrated Blaschke-Santal\'o inequality. As counterpart, we develop the basic theory of p-Rayleigh quotients in bounded domains, in the affine case, for p≥ 1. More specifically, we establish p-affine versions of the Poincar\'e inequality and some of their consequences. We introduce the affine invariant p-Laplace operator p A f defining the Euler-Lagrange equation of the minimization problem of the p-affine Rayleigh quotient. We also study its first eigenvalue λ A1,p() which satisfies the corresponding affine Faber-Krahn inequality, this is that λ A1,p() is minimized (among sets of equal volume) only when is an ellipsoid. This point depends fundamentally on PDEs regularity analysis aimed at the operator p A f. We also present some comparisons between affine and classical eigenvalues, including a result of rigidity through the characterization of equality cases for p ≥ 1. All affine inequalities obtained are stronger and directly imply the classical ones.