期刊
NANOMATERIALS
卷 13, 期 14, 页码 -出版社
MDPI
DOI: 10.3390/nano13142101
关键词
bio-inspired neuron; spiking neural networks; neuromorphic systems; synapse plasticity; Josephson effect; superconductivity
This study explores the behavior models of biological neurons using superconducting circuits and identifies new modes of operation. The study also demonstrates the possibility of switching between different modes within the system, providing dynamic control. Additionally, a synaptic connection that mimics short-term potentiation is developed and demonstrated. Simulation results of a two-neuron chain with the proposed bio-inspired components are presented, and the potential of superconducting hardware biosimilars is discussed.
The imitative modelling of processes in the brain of living beings is an ambitious task. However, advances in the complexity of existing hardware brain models are limited by their low speed and high energy consumption. A superconducting circuit with Josephson junctions closely mimics the neuronal membrane with channels involved in the operation of the sodium-potassium pump. The dynamic processes in such a system are characterised by a duration of picoseconds and an energy level of attojoules. In this work, two superconducting models of a biological neuron are studied. New modes of their operation are identified, including the so-called bursting mode, which plays an important role in biological neural networks. The possibility of switching between different modes in situ is shown, providing the possibility of dynamic control of the system. A synaptic connection that mimics the short-term potentiation of a biological synapse is developed and demonstrated. Finally, the simplest two-neuron chain comprising the proposed bio-inspired components is simulated, and the prospects of superconducting hardware biosimilars are briefly discussed.
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