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Learning transitions to extreme events using reservoir computing.

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This study uses reservoir computing machine learning to predict extreme events in dynamical systems. The approach accurately forecasts event amplitudes and transition points, preserving statistical properties.

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Area of Science:

  • Nonlinear dynamics
  • Machine learning
  • Complex systems

Background:

  • Extreme events in dynamical systems are difficult to predict due to irregular timing and large amplitudes.
  • Accurate forecasting of both amplitude and timing remains a significant challenge.

Purpose of the Study:

  • To apply reservoir computing machine learning for predicting extreme events in paradigmatic dynamical systems.
  • To evaluate the efficacy of machine learning in forecasting event transitions, amplitudes, and statistical properties.
  • To determine optimal input parameters for prediction using metrics like prediction horizon and mean square error.

Main Methods:

  • Reservoir computing machine learning was employed using partial or complete system variable information.
  • The approach was tested on the forced Liénard system, coupled FitzHugh-Nagumo model, and a hidden attractor model.
  • Numerical data and real-time experimental data from a forced Liénard circuit were used for training and validation.

Main Results:

  • The machine learning model successfully predicted transition points to extreme events via Pomeau-Manneville and crisis-induced intermittency.
  • Attractors and statistical properties (event distributions, inter-event intervals) of extreme events were accurately reproduced.
  • Time evolution prediction was limited to a few Lyapunov times, but extreme event amplitudes were preserved or accurately predicted.

Conclusions:

  • Reservoir computing offers a promising approach for predicting extreme events in complex dynamical systems.
  • The method effectively captures the dynamics and statistical characteristics of extreme events, particularly intermittency.
  • While short-term time evolution prediction is limited, amplitude forecasting and transition point prediction show high accuracy.