2019
DOI: 10.1038/s41586-019-1677-2
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Towards spike-based machine intelligence with neuromorphic computing

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Cited by 1,290 publications
(786 citation statements)
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References 127 publications
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“…Carver Mead's pioneering efforts to emulate biological information processing using analog circuits (instead of logic gates used in digital computing) and leveraging the inherent device physics of Metal Oxide Semiconductor Field Effect Transistors (MOSFETs) established a new paradigm in computing hardware (Mead, 1990). Today, neuromorphic computing encompasses the use of novel nanotechnologies such as non-volatile memory devices and memristors (memory-resistors) that can mimic synapse-like memory and spiking temporal characteristics (Yang et al, 2013;Burr et al, 2017;Ziegler et al, 2018;Roy et al, 2019). Because of their unconventional "beyond von Neumann" architecture, which substantially reduces power requirements, such devices are also attractive for implementing Artificial Neural Network (ANN) algorithms, which require computationally-intensive training to learn input-output relationships, thereby mimicking neurons and synaptic connections in software (Xu et al, 2018).…”
Section: Neuromorphic Systems: Mimicking the Brain In Hardwarementioning
confidence: 99%
“…Carver Mead's pioneering efforts to emulate biological information processing using analog circuits (instead of logic gates used in digital computing) and leveraging the inherent device physics of Metal Oxide Semiconductor Field Effect Transistors (MOSFETs) established a new paradigm in computing hardware (Mead, 1990). Today, neuromorphic computing encompasses the use of novel nanotechnologies such as non-volatile memory devices and memristors (memory-resistors) that can mimic synapse-like memory and spiking temporal characteristics (Yang et al, 2013;Burr et al, 2017;Ziegler et al, 2018;Roy et al, 2019). Because of their unconventional "beyond von Neumann" architecture, which substantially reduces power requirements, such devices are also attractive for implementing Artificial Neural Network (ANN) algorithms, which require computationally-intensive training to learn input-output relationships, thereby mimicking neurons and synaptic connections in software (Xu et al, 2018).…”
Section: Neuromorphic Systems: Mimicking the Brain In Hardwarementioning
confidence: 99%
“…The growing interest for neuromorphic computing applications is driving a fundamental shift toward memory‐centric computer architectures, enabling efficient machine learning and analysis of large data sets. [ 1–3 ] Oxygen vacancy resistive random access memory (RRAM) is seen as a promising candidate for large capacity, nonvolatile memory technologies. [ 4–6 ] In this paper, we explore for the first time the possibility of cointegration of RRAM cells and metal‐oxide‐semiconductor field‐effect‐transistors (MOSFET) selectors onto III‐V vertical nanowires (VNWs) to benefit from the advantageous transistor properties.…”
Section: Figurementioning
confidence: 99%
“…8a). Experimental results suggest that most biological networks exhibit sparse spiking activity, a feature that is presumed to underlie their superior energy-efficiency [37][38][39][40][41][42]. We investigated whether surrogate gradients could instantiate SNNs in this biologically plausible, sparse activity regime.…”
Section: Optimal Sparse Spiking Activity Levels In Snnsmentioning
confidence: 99%