Litcius/Paper detail

Task-adaptive physical reservoir computing

Oscar Lee, Tianyi Wei, Kilian D. Stenning, Jack C. Gartside, Dan Prestwood, S. Seki, Aisha Aqeel, Kosuke Karube, Naoya Kanazawa, Y. Taguchi, C. H. Back, Yoshinori Tokura, W. R. Branford, H. Kurebayashi

2023Nature Materials125 citationsDOIOpen Access PDF

Abstract

Abstract Reservoir computing is a neuromorphic architecture that may offer viable solutions to the growing energy costs of machine learning. In software-based machine learning, computing performance can be readily reconfigured to suit different computational tasks by tuning hyperparameters. This critical functionality is missing in ‘physical’ reservoir computing schemes that exploit nonlinear and history-dependent responses of physical systems for data processing. Here we overcome this issue with a ‘task-adaptive’ approach to physical reservoir computing. By leveraging a thermodynamical phase space to reconfigure key reservoir properties, we optimize computational performance across a diverse task set. We use the spin-wave spectra of the chiral magnet Cu 2 OSeO 3 that hosts skyrmion, conical and helical magnetic phases, providing on-demand access to different computational reservoir responses. The task-adaptive approach is applicable to a wide variety of physical systems, which we show in other chiral magnets via above (and near) room-temperature demonstrations in Co 8.5 Zn 8.5 Mn 3 (and FeGe).

Topics & Concepts

Reservoir computingComputer scienceNeuromorphic engineeringTask (project management)ExploitPhysical systemHyperparameterDistributed computingSet (abstract data type)Computational scienceComputer engineeringArtificial intelligenceArtificial neural networkPhysicsSystems engineeringProgramming languageRecurrent neural networkComputer securityEngineeringQuantum mechanicsNeural Networks and Reservoir ComputingAdvanced Memory and Neural ComputingNeural Networks and Applications