Your search keyword '"Namiki, Wataru"' showing total 2 results

1. Experimental Demonstration of High-Performance Physical Reservoir Computing with Nonlinear Interfered Spin Wave Multi-Detection

Author

Namiki, Wataru, Nishioka, Daiki, Yamaguchi, Yu, Tsuchiya, Takashi, Higuchi, Tohru, and Terabe, Kazuya

Subjects

FOS: Computer and information sciences, Emerging Technologies (cs.ET), FOS: Physical sciences, Computer Science - Emerging Technologies, Applied Physics (physics.app-ph), Physics - Applied Physics

Abstract

Physical reservoir computing, which is a promising method for the implementation of highly efficient artificial intelligence devices, requires a physical system with nonlinearity, fading memory, and the ability to map in high dimensions. Although it is expected that spin wave interference can perform as highly efficient reservoir computing in some micromagnetic simulations, there has been no experimental verification to date. Herein, we demonstrate reservoir computing that utilizes multidetected nonlinear spin wave interference in an yttrium iron garnet single crystal. The subject computing system achieved excellent performance when used for hand-written digit recognition, second-order nonlinear dynamical tasks, and nonlinear autoregressive moving average (NARMA). It is of particular note that normalized mean square errors (NMSEs) for NARMA2 and second-order nonlinear dynamical tasks were 1.81x10-2 and 8.37x10-5, respectively, which are the lowest figures for any experimental physical reservoir so far reported. Said high performance was achieved with higher nonlinearity and the large memory capacity of interfered spin wave multi-detection., 19 pages, 5 figures

Published

2022

2. Edge-Of-Chaos Learning Achieved by Ion-Electron Coupled Dynamics in an Ion-Gating Reservoir

Author

Nishioka, Daiki, Tsuchiya, Takashi, Namiki, Wataru, Takayanagi, Makoto, Imura, Masataka, Koide, Yasuo, Higuchi, Tohru, and Terabe, Kazuya

Subjects

FOS: Computer and information sciences, Emerging Technologies (cs.ET), FOS: Physical sciences, Computer Science - Emerging Technologies, Applied Physics (physics.app-ph), Physics - Applied Physics

Abstract

Physical reservoir computing has recently been attracting attention for its ability to significantly reduce the computational resources required to process time-series data. However, the physical reservoirs that have been reported to date have had insufficient expression power, and most of them have a large volume, which makes their practical application difficult. Herein we describe the development of a Li+-electrolyte based ion-gating reservoir (IGR), with ion-electron coupled dynamics, for use in high performance physical reservoir computing. A variety of synaptic responses were obtained in response to past experience, which responses were stored as transient charge density patterns in an electric double layer, at the Li+-electrolyte/diamond interface. Performance, which was tested using a nonlinear autoregressive moving-average (NARMA) task, was found to be excellent, with a NMSE of 0.023 for NARMA2, which is the highest for any physical reservoir reported to date. The maximum Lyapunov exponent of the IGR was 0.0083: the edge of chaos state enabling the best computational capacity. The IGR described herein opens the way for high-performance and integrated neural network devices., 25 pages, 5 figures for main part and 4 figures for Supplementary information

Published

2022