Towards sharp Bohnenblust--Hille constants
Abstract
We investigate the optimality problem associated with the best constants in a class of Bohnenblust--Hille type inequalities for --linear forms. While germinal estimates indicated an exponential growth, in this work we provide strong evidences to the conjecture that the sharp constants in the classical Bohnenblust--Hille inequality are universally bounded, irrespectively of the value of ; hereafter referred as the \textit{Universality Conjecture}. In our approach, we introduce the {notions of entropy and complexity}, designed to measure, to some extent, the complexity of such optimization problems. We show that the notion of entropy is critically connected to the Universality Conjecture; for instance, that if the entropy grows at most exponentially with respect to , then the optimal constants of the % --linear Bohnenblust--Hille inequality for real scalars are indeed bounded universally in . It is likely that indeed the entropy grows as , and in this scenario, we show that the optimal constants are precisely . In the bilinear case, , we show that any extremum of the Littlewood's -inequality has entropy and complexity , and thus we are able to classify all extrema of the problem. We also prove that, for any mixed % --Littlewood inequality, the entropy do grow exponentially and the sharp constants for such a class of inequalities are precisely . In addition to the {notions of entropy and complexity}, the approach we develop in this work makes decisive use of a family of strongly non-symmetric --linear forms, which has further consequences to the theory, as we explain herein.
Cite
@article{arxiv.1604.07595,
title = {Towards sharp Bohnenblust--Hille constants},
author = {Daniel Pellegrino and Eduardo Teixeira},
journal= {arXiv preprint arXiv:1604.07595},
year = {2018}
}
Comments
A new section was incorporated