Litcius/Paper detail

Step-like dependence of memory function on pulse width in spintronics reservoir computing

Terufumi Yamaguchi, Nozomi Akashi, Kohei Nakajima, Hitoshi Kubota, Sumito Tsunegi, Tomohiro Taniguchi

2020Scientific Reports26 citationsDOIOpen Access PDF

Abstract

Physical reservoir computing is a type of recurrent neural network that applies the dynamical response from physical systems to information processing. However, the relation between computation performance and physical parameters/phenomena still remains unclear. This study reports our progress regarding the role of current-dependent magnetic damping in the computational performance of reservoir computing. The current-dependent relaxation dynamics of a magnetic vortex core results in an asymmetric memory function with respect to binary inputs. A fast relaxation caused by a large input leads to a fast fading of the input memory, whereas a slow relaxation by a small input enables the reservoir to keep the input memory for a relatively long time. As a result, a step-like dependence is found for the short-term memory and parity-check capacities on the pulse width of input data, where the capacities remain at 1.5 for a certain range of the pulse width, and drop to 1.0 for a long pulse-width limit. Both analytical and numerical analyses clarify that the step-like behavior can be attributed to the current-dependent relaxation time of the vortex core to a limit-cycle state.

Topics & Concepts

Reservoir computingComputationPulse (music)Relaxation (psychology)VortexComputer scienceStatistical physicsFunction (biology)SpintronicsMagnetic storagePhysicsDrop (telecommunication)Range (aeronautics)Physical systemArtificial neural networkBinary numberComputational physicsCore (optical fiber)WaveformMemory modelNon-volatile memorySensitivity (control systems)Pulse-width modulationTopology (electrical circuits)Condensed matter physicsDissipationElectronic engineeringNeural Networks and Reservoir ComputingAdvanced Memory and Neural ComputingFerroelectric and Negative Capacitance Devices