Geometric Blow-Up for Folded Limit Cycle Manifolds in Three Time-Scale Systems

IF 2.6 2区 数学 Q1 MATHEMATICS, APPLIED
S. Jelbart, C. Kuehn, S.-V. Kuntz
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引用次数: 2

Abstract

Geometric singular perturbation theory provides a powerful mathematical framework for the analysis of ‘stationary’ multiple time-scale systems which possess a critical manifold, i.e. a smooth manifold of steady states for the limiting fast subsystem, particularly when combined with a method of desingularisation known as blow-up. The theory for ‘oscillatory’ multiple time-scale systems which possess a limit cycle manifold instead of (or in addition to) a critical manifold is less developed, particularly in the non-normally hyperbolic regime. We use the blow-up method to analyse the global oscillatory transition near a regular folded limit cycle manifold in a class of three time-scale ‘semi-oscillatory’ systems with two small parameters. The systems considered behave like oscillatory systems as the smallest perturbation parameter tends to zero, and stationary systems as both perturbation parameters tend to zero. The additional time-scale structure is crucial for the applicability of the blow-up method, which cannot be applied directly to the two time-scale oscillatory counterpart of the problem. Our methods allow us to describe the asymptotics and strong contractivity of all solutions which traverse a neighbourhood of the global singularity. Our main results cover a range of different cases with respect to the relative time-scale of the angular dynamics and the parameter drift. We demonstrate the applicability of our results for systems with periodic forcing in the slow equation, in particular for a class of Liénard equations. Finally, we consider a toy model used to study tipping phenomena in climate systems with periodic forcing in the fast equation, which violates the conditions of our main results, in order to demonstrate the applicability of classical (two time-scale) theory for problems of this kind.

Abstract Image

三时间尺度系统中折叠极限环流形的几何爆破
几何奇异摄动理论提供了一个强大的数学框架,用于分析具有临界流形的“平稳”多时间尺度系统,即极限快速子系统的稳态光滑流形,特别是当与称为爆破的解奇异化方法相结合时。具有极限环流形而不是(或除了)临界流形的“振荡”多时间尺度系统的理论还不太发达,特别是在非正常双曲状态下。利用爆破方法分析了一类具有两个小参数的三个时间尺度“半振荡”系统在正则折叠极限环流形附近的全局振荡跃迁。当最小的扰动参数趋于零时,所考虑的系统表现得像振荡系统,当两个扰动参数都趋于零时,所考虑的系统表现得像平稳系统。附加时标结构对爆破方法的适用性至关重要,它不能直接应用于问题的两个时标振荡对应。我们的方法允许我们描述所有解的渐近性和强收缩性,这些解穿过全局奇点的一个邻域。我们的主要结果涵盖了角动力学和参数漂移的相对时间尺度的一系列不同情况。我们证明了我们的结果对具有周期强迫的慢方程系统的适用性,特别是对一类lisamadard方程的适用性。最后,为了证明经典(双时间尺度)理论对这类问题的适用性,我们考虑了一个玩具模型,该模型用于研究快速方程中具有周期强迫的气候系统的倾斜现象,它违反了我们主要结果的条件。
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来源期刊
CiteScore
5.00
自引率
3.30%
发文量
87
审稿时长
4.5 months
期刊介绍: The mission of the Journal of Nonlinear Science is to publish papers that augment the fundamental ways we describe, model, and predict nonlinear phenomena. Papers should make an original contribution to at least one technical area and should in addition illuminate issues beyond that area''s boundaries. Even excellent papers in a narrow field of interest are not appropriate for the journal. Papers can be oriented toward theory, experimentation, algorithms, numerical simulations, or applications as long as the work is creative and sound. Excessively theoretical work in which the application to natural phenomena is not apparent (at least through similar techniques) or in which the development of fundamental methodologies is not present is probably not appropriate. In turn, papers oriented toward experimentation, numerical simulations, or applications must not simply report results without an indication of what a theoretical explanation might be. All papers should be submitted in English and must meet common standards of usage and grammar. In addition, because ours is a multidisciplinary subject, at minimum the introduction to the paper should be readable to a broad range of scientists and not only to specialists in the subject area. The scientific importance of the paper and its conclusions should be made clear in the introduction-this means that not only should the problem you study be presented, but its historical background, its relevance to science and technology, the specific phenomena it can be used to describe or investigate, and the outstanding open issues related to it should be explained. Failure to achieve this could disqualify the paper.
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