Fredholm Index of 3-Tuple of Restriction Operators and the Pair of Fringe Operators for Submodules in $$H^2({\mathbb {D}}^3)$$

IF 0.7 4区数学 Q2 MATHEMATICS

Complex Analysis and Operator Theory Pub Date : 2024-03-09 DOI:10.1007/s11785-024-01498-1

Xilin Nie, Anjian Xu

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引用次数: 0

Abstract

For a submodule ${\mathcal {M}}$ in Hardy module $H^2({\mathbb {D}}^n)$ on the unit polydisc in $\mathbb {C}^{n}$, we define the $n-1$ tuple of fringe operators $\textbf{F}=(F_{1},F_{2},\ldots ,F_{n-1})$ and the n tuple of restriction operators $\textbf{R}=(R_{z_{1}},R_{z_{2}},\ldots , R_{z_{n}})$ with respect to ${\mathcal {M}}$. In this paper, for the case $n=3$, it is shown that the fringe operators $\textbf{F}$ are Fredholm if and only if the tuple $\textbf{R}-\lambda $ is Fredholm, where $\lambda \in {\mathbb {D}}^3$, and moreover $ind(\textbf{F})=-ind(\mathbf{R-\lambda })$, which answer a question of Yang (Proc Am Math Soc 131 (2):533–541, 2003) partly and generalize a result of Luo et al. (J Math Anal Appl 465(1):531–546, 2018) in the case $n=2$. Finally, we also discuss the difference quotient operators in $H^2({\mathbb {D}}^n)$, and apply them to explore the relationship between the fringe operators and compression operators on quotient module.

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$$H^2({\mathbb {D}}^3)$$ 子模组中限制算子的三元组和边缘算子对的弗雷德霍姆指数

对于 $\mathbb {C}^{n}$ 中单位多圆盘上的哈代模块 $H^2({\mathbb {D}}^n))中的子模块 \({\mathcal {M}}$, 我们定义了边缘算子的 $n-1$ 元组 $\textbf{F}=(F_{1}、)和 n 个限制算子元组（textbf{R}=(R_{z_{1}},R_{z_{2}},\ldots ,R_{z_{n}}）。本文证明，对于 \(n=3$ 的情况，只有当 $textbf{R}-\lambda $ 元组是弗雷德霍尔姆时，边缘算子 $\textbf{F}$ 才是弗雷德霍尔姆、其中 $\lambda \in {\mathbb {D}}^3$, and moreover $ind(\textbf{F})=-ind(\mathbf{R-\lambda })$, which answer a question of Yang (Proc Am Math Soc 131 (2)：533-541, 2003）的一个问题，并部分地推广了 Luo et al.(J Math Anal Appl 465(1):531-546, 2018) 的结果。最后，我们还讨论了 $H^2({\mathbb {D}}^n)$ 中的差商算子，并应用它们探索了商模块上的边缘算子与压缩算子之间的关系。

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来源期刊

Complex Analysis and Operator Theory 数学-数学

CiteScore

1.20

自引率

12.50%

发文量

107

审稿时长

3 months

期刊介绍： Complex Analysis and Operator Theory (CAOT) is devoted to the publication of current research developments in the closely related fields of complex analysis and operator theory as well as in applications to system theory, harmonic analysis, probability, statistics, learning theory, mathematical physics and other related fields. Articles using the theory of reproducing kernel spaces are in particular welcomed.