Spiking neuron circuits using superconducting quantum phase-slip junctions

Superconducting circuits that operate by propagation of small voltage or current pulses, corresponding to propagation of single flux or charge quantum, are naturally suited for implementing spiking neuron circuits. Quantum phase-slip junctions (QPSJs) are 1-D superconducting nanowires that have been...

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Bibliographic Details
Published in:Journal of applied physics 2018-10, Vol.124 (15)
Main Authors: Cheng, Ran, Goteti, Uday S., Hamilton, Michael C.
Format: Article
Language:English
Subjects:
Applied physics
Brain
Charge transport
Circuits
CMOS
Computer simulation
Current pulses
Josephson junctions
Nanowires
Pulse propagation
Slip
Spiking
Superconductivity
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Summary:Superconducting circuits that operate by propagation of small voltage or current pulses, corresponding to propagation of single flux or charge quantum, are naturally suited for implementing spiking neuron circuits. Quantum phase-slip junctions (QPSJs) are 1-D superconducting nanowires that have been identified as exact duals to Josephson junctions, based on charge-flux duality in Maxwell’s equations. In this paper, a superconducting quantized-charge circuit element, formed using quantum phase-slip junctions, is investigated for use in high-speed, low-energy superconducting spiking neuron circuits. By means of a SPICE model developed for QPSJs, operation of this superconducting circuit to produce and transport quantized charge pulses, in the form of current pulses, is demonstrated. The resulting quantized-charge-based operation emulates spiking neuron circuits for brain-inspired neuromorphic applications. Additionally, to further demonstrate the operation of QPSJ-based neuron circuits, a QPSJ-based integrate and fire neuron circuit is introduced, along with simulation results using WRSPICE. Estimates for operating speed and power dissipation are provided and compared to Josephson junction and CMOS-based spiking neuron circuits. Current challenges are also briefly mentioned.
ISSN:0021-8979
1089-7550
DOI:10.1063/1.5042421