Predicting complex nonlinear dynamical systems has been even more urgent because of the emergence of extreme events such as earthquakes, volcanic eruptions, extreme weather events (lightning, hurricanes/cyclones, blizzards, tornadoes), and giant oceanic rogue waves, to mention a few. The recent milestones in the machine learning framework o↵er a new prospect in this area. For a high dimensional chaotic system, increasing the system’s size causes an augmentation of the complexity and, finally, the size of the artificial neural network. Here, we propose a new supervised machine learning strategy to locally forecast bursts occurring in the turbulent regime of a fiber ring cavity
A central research area in nonlinear science is the study of instabilities that drive extreme events...
We consider problems in the forecasting of large, complex, spatiotemporal chaotic systems and the po...
ACKNOWLEDGMENTS The work at Arizona State University was supported by AFOSR under Grant No. FA9550-2...
Long-term forecasting of extreme events such as oceanic rogue waves, heat waves, floods, earthquakes...
Machine learning algorithms have opened a breach in the fortress of the prediction of high-dimension...
We propose a physics-aware machine learning method to time-accurately predict extreme events in a tu...
Abstract Predicting and understanding the behavior of dynamic systems have driven advancements in va...
Forecasting the dynamics of chaotic systems from the analysis of their output signals is a challengi...
International audienceDeep Learning has received increased attention due to its unbeatable success i...
We propose a physics-constrained machine learning method—based on reservoir computing—to time-accura...
We predict the emergence of extreme events in a parametrically driven nonlinear dynamical system usi...
We propose a physics-constrained machine learning method—based on reservoir computing—to time-accura...
Forecasting the dynamics of chaotic systems from the analysis of their output signals is a challengi...
The prediction of chaotic dynamical systems’ future evolution is widely debated and represents a hot...
We propose a physics-informed Echo State Network (ESN) to predict the evolution of chaotic systems. ...
A central research area in nonlinear science is the study of instabilities that drive extreme events...
We consider problems in the forecasting of large, complex, spatiotemporal chaotic systems and the po...
ACKNOWLEDGMENTS The work at Arizona State University was supported by AFOSR under Grant No. FA9550-2...
Long-term forecasting of extreme events such as oceanic rogue waves, heat waves, floods, earthquakes...
Machine learning algorithms have opened a breach in the fortress of the prediction of high-dimension...
We propose a physics-aware machine learning method to time-accurately predict extreme events in a tu...
Abstract Predicting and understanding the behavior of dynamic systems have driven advancements in va...
Forecasting the dynamics of chaotic systems from the analysis of their output signals is a challengi...
International audienceDeep Learning has received increased attention due to its unbeatable success i...
We propose a physics-constrained machine learning method—based on reservoir computing—to time-accura...
We predict the emergence of extreme events in a parametrically driven nonlinear dynamical system usi...
We propose a physics-constrained machine learning method—based on reservoir computing—to time-accura...
Forecasting the dynamics of chaotic systems from the analysis of their output signals is a challengi...
The prediction of chaotic dynamical systems’ future evolution is widely debated and represents a hot...
We propose a physics-informed Echo State Network (ESN) to predict the evolution of chaotic systems. ...
A central research area in nonlinear science is the study of instabilities that drive extreme events...
We consider problems in the forecasting of large, complex, spatiotemporal chaotic systems and the po...
ACKNOWLEDGMENTS The work at Arizona State University was supported by AFOSR under Grant No. FA9550-2...