Scalable excitatory synaptic circuit design using floating gate based leaky integrators

Authors
Kornijcuk, VladimirLim, HyungkwangKim, InhoPark, Jong-KeukLee, Wook-SeongChoi, Jung-HaeChoi, Byung JoonJeong, Doo Seok
Issue Date
2017-12-14
Publisher
NATURE PUBLISHING GROUP
Citation
SCIENTIFIC REPORTS, v.7
Abstract
We propose a scalable synaptic circuit realizing spike timing dependent plasticity (STDP)-compatible with randomly spiking neurons. The feasible working of the circuit was examined by circuit simulation using the BSIM 4.6.0 model. A distinguishable feature of the circuit is the use of floating-gate integrators that provide the compact implementation of biologically plausible relaxation time scale. This relaxation occurs on the basis of charge tunneling that mainly relies upon area-independent tunnel barrier properties (e.g. barrier width and height) rather than capacitance. The circuit simulations feature (i) weight-dependent STDP that spontaneously limits the synaptic weight growth, (ii) competitive synaptic adaptation within both unsupervised and supervised frameworks with randomly spiking neurons. The estimated power consumption is merely 34 pW, perhaps meeting one of the most crucial principles (power-efficiency) of neuromorphic engineering. Finally, a means of fine-tuning the STDP behavior is provided.
Keywords
DEPENDENT PLASTICITY; SPIKING NEURONS; SYNAPSES; RELIABILITY; DEPENDENT PLASTICITY; SPIKING NEURONS; SYNAPSES; RELIABILITY; Scalable excitatory synaptic circuit; spike timing dependent plasticity; floating-gate integrators
ISSN
2045-2322
URI
https://pubs.kist.re.kr/handle/201004/121919
DOI
10.1038/s41598-017-17889-8
Appears in Collections:
KIST Article > 2017
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