Abstract
We explore the use of superconducting quantum phase slip junctions (QPSJs), an electromagnetic dual to Josephson Junctions (JJs), in neuromorphic circuits. These small circuits could serve as the building blocks of neuromorphic circuits for machine learning applications because they exhibit desirable properties such as inherent ultra-low energy per operation, high speed, dense integration, negligible loss, and natural spiking responses. In addition, they have a relatively straight-forward micro/nano fabrication, which shows promise for implementation of an enormous number of lossless interconnections that are required to realize complex neuromorphic systems. We simulate QPSJ-only, as well as hybrid QPSJ + JJ circuits for application in neuromorphic circuits including artificial synapses and neurons, as well as fan-in and fan-out circuits. We also design and simulate learning circuits, where a simplified spike timing dependent plasticity rule is realized to provide potential learning mechanisms. We also take an alternative approach, which shows potential to overcome some of the expected challenges of QPSJ-based neuromorphic circuits, via QPSJ-based charge islands coupled together to generate non-linear charge dynamics that result in a large number of programmable weights or non-volatile memory states. Notably, we show that these weights are a function of the timing and frequency of the input spiking signals and can be programmed using a small number of DC voltage bias signals, therefore exhibiting spike-timing and rate dependent plasticity, which are mechanisms to realize learning in neuromorphic circuits.
Highlights
Neuromorphic computing has been a rich area of study over the past several decades, bringing together the fields of electronics, biology, materials and computer science, among others (Mead, 1990)
We present results from SPICE simulations of multiple new quantum phase slip junctions (QPSJs)-based neuromorphic circuit elements and demonstrate their utility through exploration of a long term depression (LTD) circuit and a long term potentiation (LTP) circuit for use in simplified spike timing dependent plasticity (STDP) learning
While there are multiple learning strategies in neuromorphic computing, we focused on the STDP learning approach in this work to provide potential learning functions for QPSJ-based superconductive neuromorphic systems
Summary
Neuromorphic computing has been a rich area of study over the past several decades, bringing together the fields of electronics, biology, materials and computer science, among others (Mead, 1990). The non-linear switching dynamics of superconductive devices allow realization of spiking behavior with non-volatile memory in the form of spike timing dependent plasticity (STDP), which is a biologically plausible learning mechanism. With these benefits in mind, we are exploring superconductive electronics based circuits to create a scalable system of neurons and synapses that can be integrated to form learning circuits
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