Vector-valued numerical radius and $\sigma$-porosity
Abstract
It is well known that under certain conditions on a Banach space , the set of bounded linear operators attaining their numerical radius is a dense subset. We prove in this paper that if is assumed to be uniformly convex and uniformly smooth then the set of bounded linear operators attaining their numerical radius is not only a dense subset but also the complement of a -porous subset. In fact, we generalize the notion of numerical radius to a large class of vector-valued operators defined from into a Banach space and we prove that the set of all elements of strongly (up to a symmetry) attaining their {\it numerical radius} is the complement of a -porous subset of and moreover the {\it "numerical radius"} {\it Bishop-Phelps-Bollob\'as property} is also satisfied for this class. Our results extend (up to the assumption on ) some known results in several directions: the density is replaced by being the complement of a -porous subset, the operators attaining their {\it numerical radius} are replaced by operators strongly (up to a symmetry) attaining their {\it numerical radius} and the results are obtained in the vector-valued framework for general linear and non-linear vector-valued operators (including bilinear mappings and the classical space of bounded linear operators).
Cite
@article{arxiv.2212.09186,
title = {Vector-valued numerical radius and $\sigma$-porosity},
author = {Mohammed Bachir},
journal= {arXiv preprint arXiv:2212.09186},
year = {2023}
}