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Deep learning-based state prediction of the Lorenz system with control parameters

Xiaolong Wang, Jing Feng, Yong Xu, Jürgen Kurths

2024Chaos An Interdisciplinary Journal of Nonlinear Science27 citationsDOIOpen Access PDF

Abstract

Nonlinear dynamical systems with control parameters may not be well modeled by shallow neural networks. In this paper, the stable fixed-point solutions, periodic and chaotic solutions of the parameter-dependent Lorenz system are learned simultaneously via a very deep neural network. The proposed deep learning model consists of a large number of identical linear layers, which provide excellent nonlinear mapping capability. Residual connections are applied to ease the flow of information and a large training dataset is further utilized. Extensive numerical results show that the chaotic solutions can be accurately forecasted for several Lyapunov times and long-term predictions are achieved for periodic solutions. Additionally, the dynamical characteristics such as bifurcation diagrams and largest Lyapunov exponents can be well recovered from the learned solutions. Finally, the principal factors contributing to the high prediction accuracy are discussed.

Topics & Concepts

Lyapunov exponentLorenz systemNonlinear systemChaoticArtificial neural networkControl theory (sociology)Dynamical systems theoryComputer scienceResidualBifurcationApplied mathematicsMathematicsArtificial intelligenceAlgorithmControl (management)PhysicsQuantum mechanicsChaos control and synchronizationNeural Networks and Reservoir ComputingModel Reduction and Neural Networks
Deep learning-based state prediction of the Lorenz system with control parameters | Litcius