Brain-inspired nanophotonic spike computing: challenges and prospects

Bruno Romeira; Ricardo Adão; Jana B. Nieder; Qusay Al-Taai; Weikang Zhang; Robert H. Hadfield; Edward Wasige; Matěj Hejda; Antonio Hurtado; Ekaterina Malysheva; Victor Dolores Calzadilla; João Lourenço; D. Castro Alves; José M.L. Figueiredo; Ignacio Ortega-Piwonka; Julien Javaloyes; Stuart Edwards; J. Iwan Davies; Folkert Horst; Bert J. Offrein

doi:10.1088/2634-4386/acdf17

Brain-inspired nanophotonic spike computing: challenges and prospects

Bruno Romeira (Corresponding author), Ricardo Adão, Jana B. Nieder, Qusay Al-Taai, Weikang Zhang, Robert H. Hadfield, Edward Wasige, Matěj Hejda, Antonio Hurtado, Ekaterina Malysheva, Victor Dolores Calzadilla, João Lourenço, D. Castro Alves, José M.L. Figueiredo, Ignacio Ortega-Piwonka, Julien Javaloyes, Stuart Edwards, J. Iwan Davies, Folkert Horst, Bert J. Offrein

Research output: Contribution to journal › Article › Academic › peer-review

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Abstract

Nanophotonic spiking neural networks (SNNs) based on neuron-like excitable subwavelength (submicrometre) devices are of key importance for realizing brain-inspired, power-efficient artificial intelligence (AI) systems with high degree of parallelism and energy efficiency. Despite significant advances in neuromorphic photonics, compact and efficient nanophotonic elements for spiking signal emission and detection, as required for spike-based computation, remain largely unexplored. In this invited perspective, we outline the main challenges, early achievements, and opportunities toward a key-enabling photonic neuro-architecture using III-V/Si integrated spiking nodes based on nanoscale resonant tunnelling diodes (nanoRTDs) with folded negative differential resistance. We utilize nanoRTDs as nonlinear artificial neurons capable of spiking at high-speeds. We discuss the prospects for monolithic integration of nanoRTDs with nanoscale light-emitting diodes and nanolaser diodes, and nanophotodetectors to realize neuron emitter and receiver spiking nodes, respectively. Such layout would have a small footprint, fast operation, and low power consumption, all key requirements for efficient nano-optoelectronic spiking operation. We discuss how silicon photonics interconnects, integrated photorefractive interconnects, and 3D waveguide polymeric interconnections can be used for interconnecting the emitter-receiver spiking photonic neural nodes. Finally, using numerical simulations of artificial neuron models, we present spike-based spatio-temporal learning methods for applications in relevant AI-based functional tasks, such as image pattern recognition, edge detection, and SNNs for inference and learning. Future developments in neuromorphic spiking photonic nanocircuits, as outlined here, will significantly boost the processing and transmission capabilities of next-generation nanophotonic spike-based neuromorphic architectures for energy-efficient AI applications. This perspective paper is a result of the European Union funded research project ChipAI in the frame of the Horizon 2020 Future and Emerging Technologies Open programme.

Original language	English
Article number	033001
Number of pages	32
Journal	Neuromorphic Computing and Engineering
Volume	3
Issue number	3
DOIs	https://doi.org/10.1088/2634-4386/acdf17
Publication status	Published - 1 Sept 2023

Funding

Funders	Funder number
UK Research and Innovation	EP/V025198/1
European Commission	828841
European Union's Horizon 2020 - Research and Innovation Framework Programme

Keywords

nanolasers
nanoLEDs
nanophotonics
neuromorphic computing
optical interconnects
resonant tunnelling diodes
spiking neural networks

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

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Romeira, B., Adão, R., Nieder, J. B., Al-Taai, Q., Zhang, W., Hadfield, R. H., Wasige, E., Hejda, M., Hurtado, A., Malysheva, E., Dolores Calzadilla, V., Lourenço, J., Castro Alves, D., Figueiredo, J. M. L., Ortega-Piwonka, I., Javaloyes, J., Edwards, S., Davies, J. I., Horst, F., & Offrein, B. J. (2023). Brain-inspired nanophotonic spike computing: challenges and prospects. Neuromorphic Computing and Engineering, 3(3), Article 033001. https://doi.org/10.1088/2634-4386/acdf17

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title = "Brain-inspired nanophotonic spike computing: challenges and prospects",

abstract = "Nanophotonic spiking neural networks (SNNs) based on neuron-like excitable subwavelength (submicrometre) devices are of key importance for realizing brain-inspired, power-efficient artificial intelligence (AI) systems with high degree of parallelism and energy efficiency. Despite significant advances in neuromorphic photonics, compact and efficient nanophotonic elements for spiking signal emission and detection, as required for spike-based computation, remain largely unexplored. In this invited perspective, we outline the main challenges, early achievements, and opportunities toward a key-enabling photonic neuro-architecture using III-V/Si integrated spiking nodes based on nanoscale resonant tunnelling diodes (nanoRTDs) with folded negative differential resistance. We utilize nanoRTDs as nonlinear artificial neurons capable of spiking at high-speeds. We discuss the prospects for monolithic integration of nanoRTDs with nanoscale light-emitting diodes and nanolaser diodes, and nanophotodetectors to realize neuron emitter and receiver spiking nodes, respectively. Such layout would have a small footprint, fast operation, and low power consumption, all key requirements for efficient nano-optoelectronic spiking operation. We discuss how silicon photonics interconnects, integrated photorefractive interconnects, and 3D waveguide polymeric interconnections can be used for interconnecting the emitter-receiver spiking photonic neural nodes. Finally, using numerical simulations of artificial neuron models, we present spike-based spatio-temporal learning methods for applications in relevant AI-based functional tasks, such as image pattern recognition, edge detection, and SNNs for inference and learning. Future developments in neuromorphic spiking photonic nanocircuits, as outlined here, will significantly boost the processing and transmission capabilities of next-generation nanophotonic spike-based neuromorphic architectures for energy-efficient AI applications. This perspective paper is a result of the European Union funded research project ChipAI in the frame of the Horizon 2020 Future and Emerging Technologies Open programme.",

keywords = "nanolasers, nanoLEDs, nanophotonics, neuromorphic computing, optical interconnects, resonant tunnelling diodes, spiking neural networks",

author = "Bruno Romeira and Ricardo Ad{\~a}o and Nieder, {Jana B.} and Qusay Al-Taai and Weikang Zhang and Hadfield, {Robert H.} and Edward Wasige and Mat{\v e}j Hejda and Antonio Hurtado and Ekaterina Malysheva and {Dolores Calzadilla}, Victor and Jo{\~a}o Louren{\c c}o and {Castro Alves}, D. and Figueiredo, {Jos{\'e} M.L.} and Ignacio Ortega-Piwonka and Julien Javaloyes and Stuart Edwards and Davies, {J. Iwan} and Folkert Horst and Offrein, {Bert J.}",

year = "2023",

month = sep,

day = "1",

doi = "10.1088/2634-4386/acdf17",

language = "English",

volume = "3",

journal = "Neuromorphic Computing and Engineering",

issn = "2634-4386",

publisher = "IOP Publishing Ltd.",

number = "3",

}

Romeira, B, Adão, R, Nieder, JB, Al-Taai, Q, Zhang, W, Hadfield, RH, Wasige, E, Hejda, M, Hurtado, A, Malysheva, E , Dolores Calzadilla, V, Lourenço, J, Castro Alves, D, Figueiredo, JML, Ortega-Piwonka, I, Javaloyes, J, Edwards, S, Davies, JI, Horst, F & Offrein, BJ 2023, 'Brain-inspired nanophotonic spike computing: challenges and prospects', Neuromorphic Computing and Engineering, vol. 3, no. 3, 033001. https://doi.org/10.1088/2634-4386/acdf17

TY - JOUR

T1 - Brain-inspired nanophotonic spike computing

T2 - challenges and prospects

AU - Romeira, Bruno

AU - Adão, Ricardo

AU - Nieder, Jana B.

AU - Al-Taai, Qusay

AU - Zhang, Weikang

AU - Hadfield, Robert H.

AU - Wasige, Edward

AU - Hejda, Matěj

AU - Hurtado, Antonio

AU - Malysheva, Ekaterina

AU - Dolores Calzadilla, Victor

AU - Lourenço, João

AU - Castro Alves, D.

AU - Figueiredo, José M.L.

AU - Ortega-Piwonka, Ignacio

AU - Javaloyes, Julien

AU - Edwards, Stuart

AU - Davies, J. Iwan

AU - Horst, Folkert

AU - Offrein, Bert J.

PY - 2023/9/1

Y1 - 2023/9/1

N2 - Nanophotonic spiking neural networks (SNNs) based on neuron-like excitable subwavelength (submicrometre) devices are of key importance for realizing brain-inspired, power-efficient artificial intelligence (AI) systems with high degree of parallelism and energy efficiency. Despite significant advances in neuromorphic photonics, compact and efficient nanophotonic elements for spiking signal emission and detection, as required for spike-based computation, remain largely unexplored. In this invited perspective, we outline the main challenges, early achievements, and opportunities toward a key-enabling photonic neuro-architecture using III-V/Si integrated spiking nodes based on nanoscale resonant tunnelling diodes (nanoRTDs) with folded negative differential resistance. We utilize nanoRTDs as nonlinear artificial neurons capable of spiking at high-speeds. We discuss the prospects for monolithic integration of nanoRTDs with nanoscale light-emitting diodes and nanolaser diodes, and nanophotodetectors to realize neuron emitter and receiver spiking nodes, respectively. Such layout would have a small footprint, fast operation, and low power consumption, all key requirements for efficient nano-optoelectronic spiking operation. We discuss how silicon photonics interconnects, integrated photorefractive interconnects, and 3D waveguide polymeric interconnections can be used for interconnecting the emitter-receiver spiking photonic neural nodes. Finally, using numerical simulations of artificial neuron models, we present spike-based spatio-temporal learning methods for applications in relevant AI-based functional tasks, such as image pattern recognition, edge detection, and SNNs for inference and learning. Future developments in neuromorphic spiking photonic nanocircuits, as outlined here, will significantly boost the processing and transmission capabilities of next-generation nanophotonic spike-based neuromorphic architectures for energy-efficient AI applications. This perspective paper is a result of the European Union funded research project ChipAI in the frame of the Horizon 2020 Future and Emerging Technologies Open programme.

AB - Nanophotonic spiking neural networks (SNNs) based on neuron-like excitable subwavelength (submicrometre) devices are of key importance for realizing brain-inspired, power-efficient artificial intelligence (AI) systems with high degree of parallelism and energy efficiency. Despite significant advances in neuromorphic photonics, compact and efficient nanophotonic elements for spiking signal emission and detection, as required for spike-based computation, remain largely unexplored. In this invited perspective, we outline the main challenges, early achievements, and opportunities toward a key-enabling photonic neuro-architecture using III-V/Si integrated spiking nodes based on nanoscale resonant tunnelling diodes (nanoRTDs) with folded negative differential resistance. We utilize nanoRTDs as nonlinear artificial neurons capable of spiking at high-speeds. We discuss the prospects for monolithic integration of nanoRTDs with nanoscale light-emitting diodes and nanolaser diodes, and nanophotodetectors to realize neuron emitter and receiver spiking nodes, respectively. Such layout would have a small footprint, fast operation, and low power consumption, all key requirements for efficient nano-optoelectronic spiking operation. We discuss how silicon photonics interconnects, integrated photorefractive interconnects, and 3D waveguide polymeric interconnections can be used for interconnecting the emitter-receiver spiking photonic neural nodes. Finally, using numerical simulations of artificial neuron models, we present spike-based spatio-temporal learning methods for applications in relevant AI-based functional tasks, such as image pattern recognition, edge detection, and SNNs for inference and learning. Future developments in neuromorphic spiking photonic nanocircuits, as outlined here, will significantly boost the processing and transmission capabilities of next-generation nanophotonic spike-based neuromorphic architectures for energy-efficient AI applications. This perspective paper is a result of the European Union funded research project ChipAI in the frame of the Horizon 2020 Future and Emerging Technologies Open programme.

KW - nanolasers

KW - nanoLEDs

KW - nanophotonics

KW - neuromorphic computing

KW - optical interconnects

KW - resonant tunnelling diodes

KW - spiking neural networks

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U2 - 10.1088/2634-4386/acdf17

DO - 10.1088/2634-4386/acdf17

M3 - Article

AN - SCOPUS:85165239522

SN - 2634-4386

VL - 3

JO - Neuromorphic Computing and Engineering

JF - Neuromorphic Computing and Engineering

IS - 3

M1 - 033001

ER -

Brain-inspired nanophotonic spike computing: challenges and prospects

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Keywords

UN SDGs

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