English

Reservoir Computing Generalized

Chaotic Dynamics 2024-12-18 v1 Machine Learning

Abstract

A physical neural network (PNN) has both the strong potential to solve machine learning tasks and intrinsic physical properties, such as high-speed computation and energy efficiency. Reservoir computing (RC) is an excellent framework for implementing an information processing system with a dynamical system by attaching a trained readout, thus accelerating the wide use of unconventional materials for a PNN. However, RC requires the dynamics to reproducibly respond to input sequence, which limits the type of substance available for building information processors. Here we propose a novel framework called generalized reservoir computing (GRC) by turning this requirement on its head, making conventional RC a special case. Using substances that do not respond the same to identical inputs (e.g., a real spin-torque oscillator), we propose mechanisms aimed at obtaining a reliable output and show that processed inputs in the unconventional substance are retrievable. Finally, we demonstrate that, based on our framework, spatiotemporal chaos, which is thought to be unusable as a computational resource, can be used to emulate complex nonlinear dynamics, including large scale spatiotemporal chaos. Overall, our framework removes the limitation to building an information processing device and opens a path to constructing a computational system using a wider variety of physical dynamics.

Keywords

Cite

@article{arxiv.2412.12104,
  title  = {Reservoir Computing Generalized},
  author = {Tomoyuki Kubota and Yusuke Imai and Sumito Tsunegi and Kohei Nakajima},
  journal= {arXiv preprint arXiv:2412.12104},
  year   = {2024}
}
R2 v1 2026-06-28T20:37:34.649Z