Upper bounds for numerical radius inequalities involving off-diagonal operator matrices
Abstract
In this paper, we establish some upper bounds for numerical radius inequalities including of operator matrices and their off-diagonal parts. Among other inequalities, it is shown that if , then \begin{align*} \omega^{r}(T)\leq 2^{r-2}\left\|f^{2r}(|X|)+g^{2r}(|Y^*|)\right\|^\frac{1}{2}\left\|f^{2r}(|Y|)+g^{2r}(|X^*|)\right\|^\frac{1}{2} \end{align*} and \begin{align*} \omega^{r}(T)\leq 2^{r-2}\left\|f^{2r}(|X|)+f^{2r}(|Y^*|)\right\|^\frac{1}{2}\left\|g^{2r}(|Y|)+g^{2r}(|X^*|)\right\|^\frac{1}{2}, \end{align*} where are bounded linear operators on a Hilbert space , and , are nonnegative continuous functions on satisfying the relation . Moreover, we present some inequalities involving the generalized Euclidean operator radius of operators .
Cite
@article{arxiv.1706.04497,
title = {Upper bounds for numerical radius inequalities involving off-diagonal operator matrices},
author = {Mojtaba Bakherad and Khalid Shebrawi},
journal= {arXiv preprint arXiv:1706.04497},
year = {2018}
}