English

Some Berezin number inequalities for operator matrices

Functional Analysis 2018-05-04 v1 Operator Algebras

Abstract

The Berezin symbol A~\widetilde{A} of an operator AA acting on the reproducing kernel Hilbert space H=H(Ω){\mathscr H}={\mathscr H(}\Omega) over some (non-empty) set is defined by A~(λ)=Ak^λ,k^λ(λΩ)\widetilde{A}(\lambda)=\langle A\hat{k}_{\lambda},\hat{k}_{\lambda}\rangle\,\,\,(\lambda\in\Omega), where k^λ=kλkλ\hat{k}_{\lambda}=\frac{{k}_{\lambda}}{\|{k}_{\lambda}\|} is the normalized reproducing kernel of H{\mathscr H}. The Berezin number of operator AA is defined by ber(A)=supλΩA~(λ)=supλΩAk^λ,k^λ\mathbf{ber}(A) = \underset{\lambda \in \Omega}{\sup} \big|\tilde{A}(\lambda)\big|=\underset{\lambda \in \Omega }{\sup} \big|\langle A\hat{k}_{\lambda}, \hat{k}_{\lambda}\rangle\big|. Moreover ber(A)w(A)\mathbf{ber}(A)\leqslant w(A) (numerical radius). In this paper, we present some Berezin number inequalities. Among other inequalities, it is shown that if T=[ABCD]B(H(Ω1)H(Ω2))\mathbf{T}=\left[\begin{array}{cc} A&B C&D \end{array}\right]\in {\mathbb B}({\mathscr H(\Omega_1)}\oplus{\mathscr H(\Omega_2)}), then \begin{align*} \mathbf{ber}(\mathbf{T}) \leqslant\frac{1}{2}\left( \mathbf{ber}(A)+ \mathbf{ber}(D)\right)+\frac{1}{2}\sqrt{\left( \mathbf{ber}(A)- \mathbf{ber}(D)\right)^2+(\|B\|+\|C\|)^2}. \end{align*}

Keywords

Cite

@article{arxiv.1805.01015,
  title  = {Some Berezin number inequalities for operator matrices},
  author = {Mojtaba Bakherad},
  journal= {arXiv preprint arXiv:1805.01015},
  year   = {2018}
}

Comments

Czechoslovak Math. J (to appear). arXiv admin note: text overlap with arXiv:1805.01018

R2 v1 2026-06-23T01:43:21.162Z