Litcius/Paper detail

Predicting critical transitions in multiscale dynamical systems using reservoir computing

Soon Hoe Lim, Ludovico Theo Giorgini, Woosok Moon, J. S. Wettlaufer

2020Chaos An Interdisciplinary Journal of Nonlinear Science29 citationsDOIOpen Access PDF

Abstract

We study the problem of predicting rare critical transition events for a class of slow-fast nonlinear dynamical systems. The state of the system of interest is described by a slow process, whereas a faster process drives its evolution and induces critical transitions. By taking advantage of recent advances in reservoir computing, we present a data-driven method to predict the future evolution of the state. We show that our method is capable of predicting a critical transition event at least several numerical time steps in advance. We demonstrate the success as well as the limitations of our method using numerical experiments on three examples of systems, ranging from low dimensional to high dimensional. We discuss the mathematical and broader implications of our results.

Topics & Concepts

Reservoir computingNonlinear systemProcess (computing)Computer scienceDynamical systems theoryStatistical physicsEvent (particle physics)Complex systemNonlinear dynamical systemsState (computer science)Class (philosophy)Rare eventsDynamical system (definition)Mathematical optimizationAlgorithmTransition (genetics)Critical phenomenaRangingComputer simulationMathematicsApplied mathematicsNumerical analysisHigh dimensionalNeural Networks and Reservoir ComputingChaos control and synchronizationModel Reduction and Neural Networks