2019
DOI: 10.1109/tnano.2018.2871680
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Dendritic-Inspired Processing Enables Bio-Plausible STDP in Compound Binary Synapses

Abstract: Brain-inspired learning mechanisms, e.g. spike timing dependent plasticity (STDP), enable agile and fast on-thefly adaptation capability in a spiking neural network. When incorporating emerging nanoscale resistive non-volatile memory (NVM) devices, with ultra-low power consumption and highdensity integration capability, a spiking neural network hardware would result in several orders of magnitude reduction in energy consumption at a very small form factor and potentially herald autonomous learning machines. Ho… Show more

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Cited by 17 publications
(9 citation statements)
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“…When incorporating nanoscale resistive non-volatile memory components (high-density integration capability and extremely low energy consumption), a hardware with SNNs will have several orders of reduction in energy consumption. A dendriticinspired processing architecture was presented in addition to complementary metal-oxide semiconductor (CMOS) neuron circuits (Wu and Saxena, 2018). Brain-inspired circuit design is thwarted by two limits: (1) understanding the event-driven spike processing of the human brain and (2) developing predictive models for the design and optimization of cognitive circuits.…”
Section: Brain-inspired Computingmentioning
confidence: 99%
“…When incorporating nanoscale resistive non-volatile memory components (high-density integration capability and extremely low energy consumption), a hardware with SNNs will have several orders of reduction in energy consumption. A dendriticinspired processing architecture was presented in addition to complementary metal-oxide semiconductor (CMOS) neuron circuits (Wu and Saxena, 2018). Brain-inspired circuit design is thwarted by two limits: (1) understanding the event-driven spike processing of the human brain and (2) developing predictive models for the design and optimization of cognitive circuits.…”
Section: Brain-inspired Computingmentioning
confidence: 99%
“…Here, several (say M = 16) stochastic memristors were employed in parallel to obtain an approximate resolution of log 2 M = 4 bits on average. This concept was extended to include presynapstic axonal attenuation with parallel stochastic switching RRAMs [95,96]. Recently, the concept was further expanded to combine axonal (presynaptic) as well as dendritic (postsynaptic) processing [55].…”
Section: Compound Synapse With Axonal and Dendritic Processingmentioning
confidence: 99%
“…Assuming Gaussian distribution of the program/erase threshold voltages, the stochastic switching behavior of the bistable RRAM device is given by cumulative probability p(V) = P(|V| > |V th +/− |) for a voltage drop of V across the device. This is expressed as [95,96]…”
Section: Compound Synapse With Axonal and Dendritic Processingmentioning
confidence: 99%
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“…This is a new paradigm for implementing artificial neural networks using mechanisms that incorporate spike-timing dependent plasticity which is a learning algorithm discovered by neuroscientists [9] [21]. The promise of spiking networks is that they are less computationally intensive and much more energy efficient as the spiking algorithms can be implemented on a neuromorphic chip such as Intel's LOIHI chip [3] (operates at low power because it runs asynchronously using spikes) and other neuromorphic chips [40] [39] [41] [31]. Our work is based on the work of Masquelier and Thorpe [23] [22], and Kheradpisheh et al [14] [13].…”
Section: Introductionmentioning
confidence: 99%