Application of Jacobi stability analysis to a first-order dynamical system: relation between nonlinearizability of one-dimensional differential equation and Jacobi stable region

IF 1.1 Q3 PHYSICS, MULTIDISCIPLINARY Journal of Physics Communications Pub Date : 2024-03-05 DOI:10.1088/2399-6528/ad2b8c
Yuma Hirakui, Takahiro Yajima
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Abstract

In this study, we discuss Jacobi stability in equilibrium and nonequilibrium regions for a first-order one-dimensional system using deviation curvatures. The deviation curvature is calculated using the Kosambi-Cartan-Chern theory, which is applied to second-order differential equations. The deviation curvatures of the first-order one-dimensional differential equations are calculated using two methods as follows. Method 1 is only differentiating both sides of the equation. Additionally, Method 2 is differentiating both sides of the equation and then substituting the original equation into the second-order system. From the general form of the deviation curvatures calculated using each method, the analytical results are obtained as (A), (B), and (C). (A) Equilibrium points are Jacobi unstable for both methods; however, the type of equilibrium points is different. In Method 1, the equilibrium point is a nonisolated fixed point. Conversely, the equilibrium point is a saddle point in Method 2. (B) When there is a Jacobi stable region, the size of the Jacobi stable region in the Method 1 is different from that in Method 2. Especially, the Jacobi stable region in Method 1 is always larger than that in Method 2. (C) When there are multiple equilibrium points, the Jacobi stable region always exists in the nonequilibrium region located between the equilibrium points. These results are confirmed numerically using specific dynamical systems, which are given by the logistic equation and its evolution equation with the Hill function. From the results of (A) and (B), differences in types of equilibrium points affect the size of the Jacobi stable region. From (C), the Jacobi stable regions appear as nonequilibrium regions where the equations cannot be linearized.
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雅可比稳定性分析在一阶动力系统中的应用:一维微分方程的非线性化与雅可比稳定区域之间的关系
在本研究中,我们利用偏差曲率讨论了一阶一维系统在平衡和非平衡区域的雅可比稳定性。偏差曲率的计算采用了适用于二阶微分方程的 Kosambi-Cartan-Chern 理论。一阶一维微分方程的偏差曲率采用以下两种方法计算。方法 1 只对方程两边进行微分。此外,方法 2 是微分方程两边,然后将原始方程代入二阶系统。根据每种方法计算出的偏差曲率的一般形式,可得出(A)、(B)和(C)的分析结果。(A) 两种方法的平衡点都是雅可比不稳定的,但平衡点的类型不同。在方法 1 中,平衡点是一个非孤立的固定点。相反,在方法 2 中,平衡点是一个鞍点。 (B) 当存在雅可比稳定区域时,方法 1 中雅可比稳定区域的大小与方法 2 中的不同。(C) 当存在多个平衡点时,雅可比稳定区域总是存在于平衡点之间的非平衡区域。这些结果通过具体的动力学系统得到了数值证实,这些动力学系统由 logistic 方程及其希尔函数演化方程给出。从(A)和(B)的结果来看,平衡点类型的不同会影响雅可比稳定区域的大小。从(C)的结果来看,雅可比稳定区域是方程无法线性化的非平衡区域。
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来源期刊
Journal of Physics Communications
Journal of Physics Communications PHYSICS, MULTIDISCIPLINARY-
CiteScore
2.60
自引率
0.00%
发文量
114
审稿时长
10 weeks
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