The study of Lorenz and R\"ossler strange attractors by means of quantum theory

TL;DR

This paper introduces a quantum formalism for analyzing Lorenz and R"ossler chaotic systems, simplifying Lyapunov exponent calculations and offering insights into their quantum optical analogs and potential quantum computing applications.

Contribution

It develops a method to embed classical chaotic systems into quantum frameworks, enhancing analysis and computational approaches.

Findings

Simplified calculation of Lyapunov exponents using quantum formalism

Established quantum optical analogs of Lorenz and R"ossler systems

Provided a basis for quantum computational analysis of chaos

Abstract

We have developed a method for complementing an arbitrary classical dynamical system to a quantum system using the Lorenz and R\"ossler systems as examples. The Schr\"odinger equation for the corresponding quantum statistical ensemble is described in terms of the Hamilton-Jacobi formalism. We consider both the original dynamical system in the position space and the conjugate dynamical system corresponding to the momentum space. Such simultaneous consideration of mutually complementary position and momentum frameworks provides a deeper understanding of the nature of chaotic behavior in dynamical systems. We have shown that the new formalism provides a significant simplification of the Lyapunov exponents calculations. From the point of view of quantum optics, the Lorenz and R\"ossler systems correspond to three modes of a quantized electromagnetic field in a medium with cubic nonlinearity. From the computational point of view, the new formalism provides a basis for the analysis of complex dynamical systems using quantum computers.