Litcius/Paper detail

Mapping topological characteristics of dynamical systems into neural networks: A reservoir computing approach

Xiaolu Chen, Tongfeng Weng, Huijie Yang, Changgui Gu, Jie Zhang, Michael Small

2020Physical review. E30 citationsDOI

Abstract

Significant advances have recently been made in modeling chaotic systems with the reservoir computing approach, especially for prediction. We find that although state prediction of the trained reservoir computer will gradually deviate from the actual trajectory of the original system, the associated geometric features remain invariant. Specifically, we show that the typical geometric metrics including the correlation dimension, the multiscale entropy, and the memory effect are nearly identical between the trained reservoir computer and its learned chaotic systems. We further demonstrate this fact on a broad range of chaotic systems ranging from discrete and continuous chaotic systems to hyperchaotic systems. Our findings suggest that the successfully reservoir computer may be topologically conjugate to an observed dynamical system.

Topics & Concepts

Reservoir computingChaoticComputer scienceInvariant (physics)Chaotic systemsDynamical systems theoryArtificial neural networkEntropy (arrow of time)Statistical physicsTopological conjugacyTopology (electrical circuits)Theoretical computer scienceArtificial intelligenceMathematicsRecurrent neural networkPhysicsPure mathematicsCombinatoricsMathematical physicsQuantum mechanicsNeural Networks and Reservoir ComputingNeural dynamics and brain functionNeural Networks and Applications