Computer-assisted estimates for birkhoff normal forms

IF 1 Q3 Engineering

Journal of Computational Dynamics Pub Date : 2021-02-11 DOI:10.3934/jcd.2020017

Chiara Caracciolo, U. Locatelli

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引用次数: 10

Abstract

Birkhoff normal forms are commonly used in order to ensure the so called "effective stability" in the neighborhood of elliptic equilibrium points for Hamiltonian systems. From a theoretical point of view, this means that the eventual diffusion can be bounded for time intervals that are exponentially large with respect to the inverse of the distance of the initial conditions from such equilibrium points. Here, we focus on an approach that is suitable for practical applications: we extend a rather classical scheme of estimates for both the Birkhoff normal forms to any finite order and their remainders. This is made for providing explicit lower bounds of the stability time (that are valid for initial conditions in a fixed open ball), by using a fully rigorous computer-assisted procedure. We apply our approach in two simple contexts that are widely studied in Celestial Mechanics: the Henon-Heiles model and the Circular Planar Restricted Three-Body Problem. In the latter case, we adapt our scheme of estimates for covering also the case of resonant Birkhoff normal forms and, in some concrete models about the motion of the Trojan asteroids, we show that it can be more advantageous with respect to the usual non-resonant ones.

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birkhoff范式的计算机辅助估计

为了保证哈密顿系统在椭圆平衡点附近的“有效稳定性”，通常使用Birkhoff范式。从理论的角度来看，这意味着最终的扩散在时间间隔上是有界的，这个时间间隔相对于初始条件到这些平衡点的距离的倒数呈指数大。在这里，我们专注于一种适合实际应用的方法:我们将Birkhoff范式的估计扩展到任何有限阶及其余数的相当经典的方案。这是为了通过使用完全严格的计算机辅助程序提供明确的稳定时间下界(在固定的开放球的初始条件下有效)。我们将我们的方法应用于天体力学中广泛研究的两个简单背景:Henon-Heiles模型和圆平面受限三体问题。在后一种情况下，我们调整了我们的估计方案，以涵盖共振Birkhoff范式的情况，并且在一些关于特洛伊小行星运动的具体模型中，我们表明它相对于通常的非共振模型更有利。

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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来源期刊

Journal of Computational Dynamics Engineering-Computational Mechanics

CiteScore

2.30

自引率

10.00%

发文量

期刊介绍： JCD is focused on the intersection of computation with deterministic and stochastic dynamics. The mission of the journal is to publish papers that explore new computational methods for analyzing dynamic problems or use novel dynamical methods to improve computation. The subject matter of JCD includes both fundamental mathematical contributions and applications to problems from science and engineering. A non-exhaustive list of topics includes * Computation of phase-space structures and bifurcations * Multi-time-scale methods * Structure-preserving integration * Nonlinear and stochastic model reduction * Set-valued numerical techniques * Network and distributed dynamics JCD includes both original research and survey papers that give a detailed and illuminating treatment of an important area of current interest. The editorial board of JCD consists of world-leading researchers from mathematics, engineering, and science, all of whom are experts in both computational methods and the theory of dynamical systems.