Controlling chaotic maps using next-generation reservoir computing
Robert M. Kent, Wendson A. S. Barbosa, Daniel J. Gauthier
Abstract
In this work, we combine nonlinear system control techniques with next-generation reservoir computing, a best-in-class machine learning approach for predicting the behavior of dynamical systems. We demonstrate the performance of the controller in a series of control tasks for the chaotic Hénon map, including controlling the system between unstable fixed points, stabilizing the system to higher order periodic orbits, and to an arbitrary desired state. We show that our controller succeeds in these tasks, requires only ten data points for training, can control the system to a desired trajectory in a single iteration, and is robust to noise and modeling error.
Topics & Concepts
ChaoticComputer scienceController (irrigation)TrajectoryNonlinear systemControl theory (sociology)Noise (video)Hénon mapChaotic systemsDynamical systems theoryControl (management)Artificial intelligenceImage (mathematics)PhysicsQuantum mechanicsAstronomyBiologyAgronomyNeural Networks and Reservoir ComputingNeural Networks and ApplicationsModel Reduction and Neural Networks