Composition of entire function and analytic functions in the unit ball with a vanished gradient
The composition $H(z)=f(\Phi(z))$ is studied, where $f$ is an entire function of a single complex variable and $\Phi$ is an analytic function in the $n$-dimensional unit ball with a vanished gradient. We found conditions by the function $\Phi$ providing boundedness of the $\mathbf{L}$-index in join...
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| Main Authors: | , , |
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| Format: | Article |
| Language: | deu |
| Published: |
Ivan Franko National University of Lviv
2024-12-01
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| Series: | Математичні Студії |
| Subjects: | |
| Online Access: | http://matstud.org.ua/ojs/index.php/matstud/article/view/578 |
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| Summary: | The composition $H(z)=f(\Phi(z))$ is studied,
where $f$ is an entire function of a single complex variable and $\Phi$ is an analytic function
in the $n$-dimensional unit ball with a vanished gradient.
We found conditions by the function $\Phi$ providing boundedness of the $\mathbf{L}$-index in joint variables for the function $H$, if the function $f$ has bounded $l$-index for some positive continuous function $l$
and $\mathbf{L}(z)= l(\Phi(z))(\max\{1,|\Phi_{z_1}'(z)|\},\ldots, \max\{1,|\Phi_{z_n}'(z)|\}),$ $z\in\mathbb{B}^n.$
Such a constructed function $\mathbf{L}$ allows us to consider a function $\Phi$ with a nonempty zero set for its gradient.
The obtained results complement earlier published results with $\mathop{grad}\Phi(z)=(\frac{\partial \Phi(z)}{\partial z_1}, \ldots, \frac{\partial \Phi(z)}{\partial z_j},\ldots,\frac{\partial \Phi(z)}{\partial z_n})\ne \mathbf{0}.$
Also, we study a more general composition $H(\mathbf{w})=G(\mathbf{\Phi}(\mathbf{w}))$, where
$G: \mathbb{C}^n\to \mathbb{C}$ is an entire function of the bounded $\mathbf{L}$-index in joint variables,
$\mathbf{\Phi}: \mathbb{B}^m\to \mathbb{C}^n$ is a vector-valued analytic function, and
$\mathbf{L}: \mathbb{C}^n\to\mathbb{R}^n_+$ is a continuous function.
If the $\mathbf{L}$-index of the function $G$ equals zero, then we construct a function
$\widetilde{\mathbf{L}}: \mathbb{B}^m\to\mathbb{R}^m_+$ such that the function $H$ has bounded
$\widetilde{\mathbf{L}}$-index in the joint variables $w_1,$ $\ldots,$ $w_m$.
These results are also new in one-dimensional case, i.e. for functions analytic in the unit disc. |
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| ISSN: | 1027-4634 2411-0620 |