Jacobi stability analysis of the Lorenz system

TL;DR

This paper applies Jacobi stability analysis via KCC theory to the Lorenz system, providing a geometric perspective on its stability and deriving conditions for equilibrium stability.

Contribution

It introduces a geometric approach using Finsler space and KCC theory to analyze Lorenz system stability, which is novel in this context.

Findings

Jacobi stability conditions for Lorenz system equilibrium points derived

Explicit geometric invariants and eigenvalues calculated

Stability conditions linked to deviation vector evolution near equilibria

Abstract

We perform the study of the stability of the Lorenz system by using the Jacobi stability analysis, or the Kosambi-Cartan-Chern (KCC) theory. The Lorenz model plays an important role for understanding hydrodynamic instabilities and the nature of the turbulence, also representing a non-trivial testing object for studying non-linear effects. The KCC theory represents a powerful mathematical method for the analysis of dynamical systems. In this approach we describe the evolution of the Lorenz system in geometric terms, by considering it as a geodesic in a Finsler space. By associating a non-linear connection and a Berwald type connection, five geometrical invariants are obtained, with the second invariant giving the Jacobi stability of the system. The Jacobi (in)stability is a natural generalization of the (in)stability of the geodesic flow on a differentiable manifold endowed with a metric (Riemannian or Finslerian) to the non-metric setting. In order to apply the KCC theory we reformulate the Lorenz system as a set of two second order non-linear differential equations. The geometric invariants associated to this system (nonlinear and Berwald connections), and the deviation curvature tensor, as well as its eigenvalues, are explicitly obtained. The Jacobi stability of the equilibrium points of the Lorenz system is studied, and the condition of the stability of the equilibrium points is obtained. Finally, we consider the time evolution of the components of the deviation vector near the equilibrium points.