Artificial Neuron Based on Integrated Semiconductor Quantum Dot Mode-Locked Lasers

Mesaritakis, Charis; Kapsalis, A.; Bogris, Adonis; Syvridis, Dimitris

doi:10.1038/srep39317

Cited by 76 publications

(35 citation statements)

References 64 publications

(82 reference statements)

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“…Meanwhile, on account of changes in the physical representations of information, photonic spike processing has emerged as high‐speed, low‐power computational domain that is inaccessible by pure electronic devices . Photonic synapses based on an amorphous metal‐sulfide microfiber, graphene‐coupled laser system, and phase change material have recently been demonstrated by exploiting light as the input and output signals.…”

Section: Introductionmentioning

confidence: 99%

Optoelectronic Synapse Based on IGZO‐Alkylated Graphene Oxide Hybrid Structure

Sun

Choi

et al. 2018

Adv Funct Materials

309

275

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Recently, research interest in brain-inspired neuromorphic computing based on robust and intelligent artificial neural networks has surged owing to the ability of such technology to facilitate massive parallel, low-power, highly adaptive, and event-driven computing. Here, a photosynaptic device with a novel weight updating mechanism for high-speed and low-power optoelectronic spike processing is proposed, wherein a synaptic weight is controlled by a mixed spike consisting of voltage and light spikes; the light spike, in particular, boosts up the probability of electron detrapping from graphene oxide charge-trapping layer to the photosensitive indium-gallium-zinc oxide charge-transporting layer. Compared to electrically operating synaptic device, the magnitude of conductance change in the proposed photosynaptic device increases remarkably from 2.32 to 5.95 nS without degradation of the nonlinearity (potentiation/depression values are changed from 4.24/8 to 5/8). Owing to this enhancement of synaptic operation, the recognition rates for the Modified National Institute of Standards and Technology digit patterns improve from 36% and 49% to 50% and 62% in artificial neural networks using long-term potentiation/depression characteristics with 20 and 100 weight states, respectively. The proposed photosynaptic device technology capable of optoelectronic spike processing is expected to play a crucial role in the implementation of neuromorphic computing in the future.

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Section: Introductionmentioning

confidence: 99%

Optoelectronic Synapse Based on IGZO‐Alkylated Graphene Oxide Hybrid Structure

Sun

Choi

et al. 2018

Adv Funct Materials

309

275

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“…Modulators combined with photodetectors [23,24], SOA-MZIs [19,38] and laser-cooled atoms with electro-magnetically induced transparency [25] are used to realize the nonlinear activation function in ANN. Meanwhile, lasers, e.g., micro-pillar lasers [36], two-section lasers with saturable absorber regions [26,27], vertical-cavity surface-emitting lasers (VCSELs) [34,35,37,40] and quantum dot (QD) lasers [39] are typically used to implement the functionality of spiking neurons in SNN. Owing to its unique optical properties in different states, phase change material (PCM) has emerged as an attractive alternative to provide in hardware both the basic integrate-andfire functionality of neurons and the plastic weighting operation of synapses [28][29][30][31].…”

Section: Introductionmentioning

confidence: 99%

All-Optical Spiking Neuron Based on Passive Microresonator

Xiang

Torchy

Guo

et al. 2020

J. Lightwave Technol.

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Neuromorphic photonics that aims to process and store information simultaneously like human brains has emerged as a promising alternative for the next generation intelligent computing systems. The implementation of hardware emulating the basic functionality of neurons and synapses is the fundamental work in this field. However, previously proposed optical neurons implemented with SOA-MZIs, modulators, lasers or phase change materials are all dependent on active devices and quite difficult for integration. Meanwhile, although the nonlinearity in nanocavities has long been of interest, the previous theories are intended for specific situations, e.g., selfpulsation in microrings, and there is still a lack of systematic studies in the excitability behavior of the nanocavities including the silicon photonic crystal cavities. Here, we report for the first time a universal coupled mode theory model for all side-coupled passive microresonators. Attributed to the nonlinear excitability, the passive microresonator can function as a new type of all-optical spiking neuron. We demonstrate the microresonator-based neuron can exhibit the three most important characteristics of spiking neurons: excitability threshold, refractory period and cascadability behavior, paving the way to realize all-optical spiking neural networks.

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“…Different nonlinear activation functions with significantly different ranges and trends 14 have been proposed and extensively investigated, providing suitable advantages according to the different applications. More in details, interesting experimental and numerical all-optical nonlinear module based on saturable and reverse absorption 15,16 , graphene excitable lasers 17,18 , twosection distributed-feedback (DFB) lasers 19 , quantum dots 20 , disks lasers 21,22 , induced transparency in quantum assembly 15 have recently been reported and showed promising results in terms of efficiency and throughput for different kinds of neural network and applications, ranging from convolutional neural network, spiking neural network and reservoir computing. Although, a more straightforward implementation is currently attained by exploiting electro-optic tuned nonlinear materials 23,24 or absorptive modulator directly connected to a photodiode, as shown in 14,[25][26][27][28] .…”

Section: Introductionmentioning

confidence: 99%

ITO-based electro-absorption modulator for photonic neural activation function

et al. 2019

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Recently integrated optics has become an intriguing platform for implementing machine learning algorithms and in particular neural networks. Integrated photonic circuits can straightforwardly perform vector-matrix multiplications with high efficiency and low power consumption by using weighting mechanism through linear optics. Although, this can not be said for the activation function which requires either nonlinear optics or an electro-optic module with an appropriate dynamic range. Even though all-optical nonlinear optics is potentially faster, its current integration is challenging and is rather inefficient. Here we demonstrate an electro-absorption modulator based on an Indium Tin Oxide layer, whose dynamic range is used as nonlinear activation function of a photonic neuron. The nonlinear activation mechanism is based on a photodiode, which integrates the weighed products, and whose photovoltage drives the elecro-absorption modulator. The synapse and neuron circuit is then constructed to execute a 200-node MNIST classification neural network used for benchmarking the nonlinear activation function and compared with an equivalent electronic module.

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Artificial Neuron Based on Integrated Semiconductor Quantum Dot Mode-Locked Lasers

Cited by 76 publications

References 64 publications

Optoelectronic Synapse Based on IGZO‐Alkylated Graphene Oxide Hybrid Structure

Optoelectronic Synapse Based on IGZO‐Alkylated Graphene Oxide Hybrid Structure

All-Optical Spiking Neuron Based on Passive Microresonator

ITO-based electro-absorption modulator for photonic neural activation function

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