立方体系统家族的全球中心

Pub Date : 2024-04-05 DOI:10.1007/s00010-024-01051-7

Raul Felipe Appis, Jaume Llibre

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引用次数: 0

摘要

考虑平面 $\mathbb {R}^2$ 中的 3 度多项式微分系统族，或者简单的立方系统 $$ x' = y, \quad y' = -x + a_1 x^2 + a_2 xy + a_3 y^2 + a_4 x^3 + a_5 x^2 y + a_6 xy^2 + a_7 y^3, $$。如果存在一个 $(x_0,y_0)$ 的邻域 $\mathcal {U}$ 使得 $\mathcal {U}$ 是一个中心，那么平面微分系统的平衡点 $(x_0,y_0)$ 就是一个中心。\充满了周期性的轨道。当 \(\mathbb {R}^2\setminus \{(x_0,y_0)\})充满了周期性轨道时，那么中心就是全局中心。劳埃德和皮尔逊（Comput Math Appl 60:2797-2805, 2010）在《计算数学应用 60：2797-2805，2010》一文中描述了这个立方系统家族中坐标原点为中心时的特征。我们对这些中心中哪些是全局中心进行了分类。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Global centers of a family of cubic systems

Consider the family of polynomial differential systems of degree 3, or simply cubic systems

$$ x' = y, \quad y' = -x + a_1 x^2 + a_2 xy + a_3 y^2 + a_4 x^3 + a_5 x^2 y + a_6 xy^2 + a_7 y^3, $$

in the plane $\mathbb {R}^2$. An equilibrium point $(x_0,y_0)$ of a planar differential system is a center if there is a neighborhood $\mathcal {U}$ of $(x_0,y_0)$ such that $\mathcal {U} \backslash \{(x_0,y_0)\}$ is filled with periodic orbits. When $\mathbb {R}^2\setminus \{(x_0,y_0)\}$ is filled with periodic orbits, then the center is a global center. For this family of cubic systems Lloyd and Pearson characterized in Lloyd and Pearson (Comput Math Appl 60:2797–2805, 2010) when the origin of coordinates is a center. We classify which of these centers are global centers.

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