Four Limit Cycles of Three-Dimensional Discontinuous Piecewise Differential Systems Having a Sphere as Switching Manifold

IF 1.9 4区 数学 Q2 MATHEMATICS, INTERDISCIPLINARY APPLICATIONS International Journal of Bifurcation and Chaos Pub Date : 2024-03-06 DOI:10.1142/s0218127424500305
Louiza Baymout, Rebiha Benterki
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Abstract

Because of their applications, the study of piecewise-linear differential systems has become increasingly important in recent years. This type of system already exists to model many different natural phenomena in physics, biology, economics, etc. As is well known, the study of the qualitative theory of piecewise differential systems focuses mainly on limit cycles. Most papers studying the problem of existence and the maximum number of limit cycles of piecewise differential systems have precisely considered planar systems. However, few papers have examined this problem in 3. In this paper, our main goal is to examine a class of discontinuous piecewise differential systems in 3, where we consider the unit sphere as the separation surface that divides the entire space into two regions, each one has a linear vector field analogous to planar center. In general, it is hard to determine an exact upper bound for the number of limit cycles that a class of differential systems can exhibit. We prove that this class of differential systems can have at most four limit cycles. We show that there are examples of such differential systems with exactly 1, 2, 3 and 4 limit cycles.

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以球面为切换平面的三维非连续片断微分系统的四个极限循环
近年来,片线性微分系统的研究因其应用而变得越来越重要。这类系统已经可以模拟物理学、生物学、经济学等领域的许多不同自然现象。众所周知,片线性微分系统的定性理论研究主要集中在极限循环上。大多数研究片断微分系统存在性和极限循环最大次数问题的论文都精确地考虑了平面系统。然而,很少有论文研究ℝ3 中的这一问题。在本文中,我们的主要目标是研究ℝ3 中的一类不连续片断微分系统,其中我们将单位球面视为将整个空间划分为两个区域的分离面,每个区域都有一个类似于平面中心的线性向量场。一般来说,很难确定一类微分系统的极限循环次数的精确上限。我们证明,这一类微分系统最多可以有四个极限循环。我们还证明了这类微分系统中恰好有 1、2、3 和 4 个极限循环的例子。
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来源期刊
International Journal of Bifurcation and Chaos
International Journal of Bifurcation and Chaos 数学-数学跨学科应用
CiteScore
4.10
自引率
13.60%
发文量
237
审稿时长
2-4 weeks
期刊介绍: The International Journal of Bifurcation and Chaos is widely regarded as a leading journal in the exciting fields of chaos theory and nonlinear science. Represented by an international editorial board comprising top researchers from a wide variety of disciplines, it is setting high standards in scientific and production quality. The journal has been reputedly acclaimed by the scientific community around the world, and has featured many important papers by leading researchers from various areas of applied sciences and engineering. The discipline of chaos theory has created a universal paradigm, a scientific parlance, and a mathematical tool for grappling with complex dynamical phenomena. In every field of applied sciences (astronomy, atmospheric sciences, biology, chemistry, economics, geophysics, life and medical sciences, physics, social sciences, ecology, etc.) and engineering (aerospace, chemical, electronic, civil, computer, information, mechanical, software, telecommunication, etc.), the local and global manifestations of chaos and bifurcation have burst forth in an unprecedented universality, linking scientists heretofore unfamiliar with one another''s fields, and offering an opportunity to reshape our grasp of reality.
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