Litcius/Paper detail

Superconducting disordered neural networks for neuromorphic processing with fluxons

Uday S. Goteti, Han Cai, Jay C. LeFebvre, Shane A. Cybart, R. C. Dynes

2022Science Advances21 citationsDOIOpen Access PDF

Abstract

In superconductors, magnetic fields are quantized into discrete fluxons (flux quanta Φ 0 ), made of microscopic circulating supercurrents. We introduce a multiterminal synapse network comprising a disordered array of superconducting loops with Josephson junctions. The loops can trap fluxons defining memory, while the junctions allow their movement between loops. Dynamics of fluxons through such a disordered system through a complex reconfigurable energy landscape represents brain-like spiking information flow. In this work, we experimentally demonstrate a three-loop network using YBa 2 Cu 3 O 7 − δ -based superconducting loops and Josephson junctions, which exhibit stable memory configurations of trapped flux in loops that determine the rate of flow of fluxons through synaptic connections. The memory states are, in turn, affected by the applied input signals but can also be externally configured electrically through control current/feedback terminals. These results establish a previously unexplored, biologically similar architectural approach to neuromorphic computing that is scalable while dissipating energy of atto Joules/spike.

Topics & Concepts

Neuromorphic engineeringJosephson effectPhysicsFluxonSuperconductivitySpiking neural networkArtificial neural networkEnergy (signal processing)Condensed matter physicsTopology (electrical circuits)Computer sciencePi Josephson junctionElectrical engineeringQuantum mechanicsArtificial intelligenceEngineeringAdvanced Memory and Neural ComputingNeural Networks and Reservoir ComputingNeural dynamics and brain function