的数值半径点 ${\mathcal L}(^m l_{\infty}^n:l_{\infty}^n)$

Q4 Mathematics New Zealand Journal of Mathematics Pub Date : 2022-10-12 DOI:10.53733/179

Sung Guen Kim

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引用次数: 1

摘要

因为 $n\geq 2$ 和一个真正的巴拿赫空间 $E,$ ${\mathcal L}(^n E:E)$ 表示所有连续的空间 $n$-线性映射 $E$ 自言自语。让 $$\Pi(E)=\Big\{~[x^*, (x_1, \ldots, x_n)]: x^{*}(x_j)=\|x^{*}\|=\|x_j\|=1~\mbox{for}~{j=1, \ldots, n}~\Big\}.$$因为 $T\in {\mathcal L}(^n E:E),$ 我们定义 $${\rm Nrad}({T})=\Big\{~[x^*, (x_1, \ldots, x_n)]\in \Pi(E): |x^{*}(T(x_1, \ldots, x_n))|=v(T)~\Big\},$$在哪里 $v(T)$ 的数值半径 $T$．$T$ 叫做 {\em 数值半径峰映射} 如果有的话 $[x^{*}, (x_1, \ldots, x_n)]\in \Pi(E)$ 这满足 ${\rm Nrad}({T})=\Big\{~\pm [x^{*}, (x_1, \ldots, x_n)]~\Big\}.$在本文中，我们进行了分类 ${\rm Nrad}({T})$ 对于每一个 $T\in {\mathcal L}(^2 l_{\infty}^2: l_{\infty}^2)$ 的范数达到点的集合 $T$我们也描述了所有数值半径峰映射 ${\mathcalL}(^m l_{\infty}^n:l_{\infty}^n)$ 为了 $n, m\geq 2,$ 在哪里 $l_{\infty}^n=\mathbb{R}^n$ 用最高规范。

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Numerical radius points of ${\mathcal L}(^m l_{\infty}^n:l_{\infty}^n)$

For $n\geq 2$ and a real Banach space $E,$ ${\mathcal L}(^n E:E)$ denotes the space of all continuous $n$-linear mappings from $E$ to itself.Let $$\Pi(E)=\Big\{~[x^*, (x_1, \ldots, x_n)]: x^{*}(x_j)=\|x^{*}\|=\|x_j\|=1~\mbox{for}~{j=1, \ldots, n}~\Big\}.$$For $T\in {\mathcal L}(^n E:E),$ we define $${\rm Nrad}({T})=\Big\{~[x^*, (x_1, \ldots, x_n)]\in \Pi(E): |x^{*}(T(x_1, \ldots, x_n))|=v(T)~\Big\},$$where $v(T)$ denotes the numerical radius of $T$.$T$ is called {\em numerical radius peak mapping} if there is $[x^{*}, (x_1, \ldots, x_n)]\in \Pi(E)$ that satisfies ${\rm Nrad}({T})=\Big\{~\pm [x^{*}, (x_1, \ldots, x_n)]~\Big\}.$ In this paper we classify ${\rm Nrad}({T})$ for every $T\in {\mathcal L}(^2 l_{\infty}^2: l_{\infty}^2)$ in connection with the set of the norm attaining points of $T$.We also characterize all numerical radius peak mappings in ${\mathcalL}(^m l_{\infty}^n:l_{\infty}^n)$ for $n, m\geq 2,$ where $l_{\infty}^n=\mathbb{R}^n$ with the supremum norm.

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