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Magnetization Vector Rotation Reservoir Computing Operated by Redox Mechanism

Wataru Namiki, Daiki Nishioka, Takashi Tsuchiya, Tohru Higuchi, Kazuya Terabe

2024Nano Letters21 citationsDOIOpen Access PDF

Abstract

Physical reservoir computing is a promising way to develop efficient artificial intelligence using physical devices exhibiting nonlinear dynamics. Although magnetic materials have advantages in miniaturization, the need for a magnetic field and large electric current results in high electric power consumption and a complex device structure. To resolve these issues, we propose a redox-based physical reservoir utilizing the planar Hall effect and anisotropic magnetoresistance, which are phenomena described by different nonlinear functions of the magnetization vector that do not need a magnetic field to be applied. The expressive power of this reservoir based on a compact all-solid-state redox transistor is higher than the previous physical reservoir. The normalized mean square error of the reservoir on a second-order nonlinear equation task was 1.69 × 10 –3, which is lower than that of a memristor array (3.13 × 10 –3 ) even though the number of reservoir nodes was fewer than half that of the memristor array.

Topics & Concepts

MagnetoresistanceMagnetizationReservoir computingNonlinear systemMagnetic fieldComputer scienceMiniaturizationElectric fieldMaterials sciencePhysicsCondensed matter physicsNanotechnologyQuantum mechanicsArtificial intelligenceArtificial neural networkRecurrent neural networkNeural Networks and Reservoir ComputingAdvanced Memory and Neural ComputingNeural dynamics and brain function
Magnetization Vector Rotation Reservoir Computing Operated by Redox Mechanism | Litcius