Time-multiplexed System-on-Chip using Fault-tolerant Astrocyte-Neuron Networks

Anju P. Johnson; Junxiu Liu; Alan G. Millard; Shvan Karim; Andy M. Tyrrell; Jim Harkin; Jon Timmis; Liam McDaid; David M. Halliday

doi:10.1109/SSCI.2018.8628710

Time-multiplexed System-on-Chip using Fault-tolerant Astrocyte-Neuron Networks

Anju P. Johnson, Junxiu Liu, Alan G. Millard, Shvan Karim, Andy M. Tyrrell, Jim Harkin, Jon Timmis, Liam McDaid, David M. Halliday

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Allbwn ymchwil: Pennod mewn Llyfr/Adroddiad/Trafodion Cynhadledd › Trafodion Cynhadledd (Nid-Cyfnodolyn fathau)

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Spike-based brain-inspired systems have shown an immense capability to achieve internal stability, widely referred to as homeostasis. This ability enrols them as the best candidate for next-generation computational neuroscience as they bridge the gap between neuroscience and machine learning. Spiking Neural Networks (SNN), a third generation Artificial Neural Network (ANN), which operates using discrete events of spikes, contributes to a category of biologically-realistic models of neurons to carry out computations. Spiking Astrocyte-Neuron Networks (SANN) have a characteristic attribute homologous to brain self-repair. Although SNNs are more powerful in theory than 2nd generation ANNs, they are not widely in use as their implementations on normal hardware are computationally-intensive. On the contrary, due to the capability of modern hardware such as FPGAs, which operates in MHz and GHz range, facilitates real-time and faster-than-real-time simulations of SNNs. In this work, we overcome the computational overhead of the SNNs using the benefits of real-time hardware computations, utilizing time-multiplexing to design a Self-rePairing spiking Astrocyte Neural NEtwoRk (SPANNER) chip, generic to users' choice of task, emphasizing fault-tolerance, targeting safety-critical applications. We demonstrate the proposed methodology on a SANN system implemented on Xilinx Artix-7 FPGA. The proposed architecture has minimal hardware footprints, power dissipation profile and real-time computational capability, enhancing its usability in constrained applications.

Iaith wreiddiol	Saesneg
Teitl	Proceedings of the 2018 IEEE Symposium Series on Computational Intelligence, SSCI 2018
Golygyddion	Suresh Sundaram
Cyhoeddwr	IEEE Press
Tudalennau	1076-1083
Nifer y tudalennau	8
ISBN (Electronig)	9781538692769
Dynodwyr Gwrthrych Digidol (DOIs)	https://doi.org/10.1109/SSCI.2018.8628710
Statws	Cyhoeddwyd - 02 Gorff 2018
Digwyddiad	8th IEEE Symposium Series on Computational Intelligence, SSCI 2018 - Bangalore, India Hyd: 18 Tach 2018 → 21 Tach 2018

Cyfres gyhoeddiadau

Enw	Proceedings of the 2018 IEEE Symposium Series on Computational Intelligence, SSCI 2018

Cynhadledd

Cynhadledd	8th IEEE Symposium Series on Computational Intelligence, SSCI 2018
Gwlad/Tiriogaeth	India
Dinas	Bangalore
Cyfnod	18 Tach 2018 → 21 Tach 2018

Mynediad at Ddogfen

10.1109/SSCI.2018.8628710

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Johnson, A. P., Liu, J., Millard, A. G., Karim, S., Tyrrell, A. M., Harkin, J., Timmis, J., McDaid, L., & Halliday, D. M. (2018). Time-multiplexed System-on-Chip using Fault-tolerant Astrocyte-Neuron Networks. Yn S. Sundaram (Gol.), Proceedings of the 2018 IEEE Symposium Series on Computational Intelligence, SSCI 2018 (tt. 1076-1083). erthygl 8628710 (Proceedings of the 2018 IEEE Symposium Series on Computational Intelligence, SSCI 2018). IEEE Press. https://doi.org/10.1109/SSCI.2018.8628710

Johnson, Anju P. ; Liu, Junxiu ; Millard, Alan G. et al. / Time-multiplexed System-on-Chip using Fault-tolerant Astrocyte-Neuron Networks. Proceedings of the 2018 IEEE Symposium Series on Computational Intelligence, SSCI 2018. Gol. / Suresh Sundaram. IEEE Press, 2018. tt. 1076-1083 (Proceedings of the 2018 IEEE Symposium Series on Computational Intelligence, SSCI 2018).

@inproceedings{41b1dd57511744a8af75dba9236991a8,

title = "Time-multiplexed System-on-Chip using Fault-tolerant Astrocyte-Neuron Networks",

abstract = "Spike-based brain-inspired systems have shown an immense capability to achieve internal stability, widely referred to as homeostasis. This ability enrols them as the best candidate for next-generation computational neuroscience as they bridge the gap between neuroscience and machine learning. Spiking Neural Networks (SNN), a third generation Artificial Neural Network (ANN), which operates using discrete events of spikes, contributes to a category of biologically-realistic models of neurons to carry out computations. Spiking Astrocyte-Neuron Networks (SANN) have a characteristic attribute homologous to brain self-repair. Although SNNs are more powerful in theory than 2nd generation ANNs, they are not widely in use as their implementations on normal hardware are computationally-intensive. On the contrary, due to the capability of modern hardware such as FPGAs, which operates in MHz and GHz range, facilitates real-time and faster-than-real-time simulations of SNNs. In this work, we overcome the computational overhead of the SNNs using the benefits of real-time hardware computations, utilizing time-multiplexing to design a Self-rePairing spiking Astrocyte Neural NEtwoRk (SPANNER) chip, generic to users' choice of task, emphasizing fault-tolerance, targeting safety-critical applications. We demonstrate the proposed methodology on a SANN system implemented on Xilinx Artix-7 FPGA. The proposed architecture has minimal hardware footprints, power dissipation profile and real-time computational capability, enhancing its usability in constrained applications.",

keywords = "Astrocytes, Bio-inspired Engineering, Fault Tolerance, FPGA, Neuromorphic Computing, Self-Repair, Spiking Neural Networks, Time Multiplexing",

author = "Johnson, {Anju P.} and Junxiu Liu and Millard, {Alan G.} and Shvan Karim and Tyrrell, {Andy M.} and Jim Harkin and Jon Timmis and Liam McDaid and Halliday, {David M.}",

note = "Funding Information: The work is part of the SPANNER project and is funded by EPSRC grant–(EP/N007050/1, EP/N00714X/1). Additionally, the authors would like to acknowledge the platform grant– (EP/K040820/1) funded by EPSRC. Publisher Copyright: {\textcopyright} 2018 IEEE.; 8th IEEE Symposium Series on Computational Intelligence, SSCI 2018 ; Conference date: 18-11-2018 Through 21-11-2018",

year = "2018",

month = jul,

day = "2",

doi = "10.1109/SSCI.2018.8628710",

language = "English",

series = "Proceedings of the 2018 IEEE Symposium Series on Computational Intelligence, SSCI 2018",

publisher = "IEEE Press",

pages = "1076--1083",

editor = "Suresh Sundaram",

booktitle = "Proceedings of the 2018 IEEE Symposium Series on Computational Intelligence, SSCI 2018",

address = "United States of America",

}

Johnson, AP, Liu, J, Millard, AG, Karim, S, Tyrrell, AM, Harkin, J, Timmis, J, McDaid, L & Halliday, DM 2018, Time-multiplexed System-on-Chip using Fault-tolerant Astrocyte-Neuron Networks. yn S Sundaram (gol.), Proceedings of the 2018 IEEE Symposium Series on Computational Intelligence, SSCI 2018., 8628710, Proceedings of the 2018 IEEE Symposium Series on Computational Intelligence, SSCI 2018, IEEE Press, tt. 1076-1083, 8th IEEE Symposium Series on Computational Intelligence, SSCI 2018, Bangalore, India, 18 Tach 2018. https://doi.org/10.1109/SSCI.2018.8628710

Time-multiplexed System-on-Chip using Fault-tolerant Astrocyte-Neuron Networks. / Johnson, Anju P.; Liu, Junxiu; Millard, Alan G. et al.
Proceedings of the 2018 IEEE Symposium Series on Computational Intelligence, SSCI 2018. gol. / Suresh Sundaram. IEEE Press, 2018. t. 1076-1083 8628710 (Proceedings of the 2018 IEEE Symposium Series on Computational Intelligence, SSCI 2018).

Allbwn ymchwil: Pennod mewn Llyfr/Adroddiad/Trafodion Cynhadledd › Trafodion Cynhadledd (Nid-Cyfnodolyn fathau)

TY - GEN

T1 - Time-multiplexed System-on-Chip using Fault-tolerant Astrocyte-Neuron Networks

AU - Johnson, Anju P.

AU - Liu, Junxiu

AU - Millard, Alan G.

AU - Karim, Shvan

AU - Tyrrell, Andy M.

AU - Harkin, Jim

AU - Timmis, Jon

AU - McDaid, Liam

AU - Halliday, David M.

N1 - Funding Information: The work is part of the SPANNER project and is funded by EPSRC grant–(EP/N007050/1, EP/N00714X/1). Additionally, the authors would like to acknowledge the platform grant– (EP/K040820/1) funded by EPSRC. Publisher Copyright: © 2018 IEEE.

PY - 2018/7/2

Y1 - 2018/7/2

N2 - Spike-based brain-inspired systems have shown an immense capability to achieve internal stability, widely referred to as homeostasis. This ability enrols them as the best candidate for next-generation computational neuroscience as they bridge the gap between neuroscience and machine learning. Spiking Neural Networks (SNN), a third generation Artificial Neural Network (ANN), which operates using discrete events of spikes, contributes to a category of biologically-realistic models of neurons to carry out computations. Spiking Astrocyte-Neuron Networks (SANN) have a characteristic attribute homologous to brain self-repair. Although SNNs are more powerful in theory than 2nd generation ANNs, they are not widely in use as their implementations on normal hardware are computationally-intensive. On the contrary, due to the capability of modern hardware such as FPGAs, which operates in MHz and GHz range, facilitates real-time and faster-than-real-time simulations of SNNs. In this work, we overcome the computational overhead of the SNNs using the benefits of real-time hardware computations, utilizing time-multiplexing to design a Self-rePairing spiking Astrocyte Neural NEtwoRk (SPANNER) chip, generic to users' choice of task, emphasizing fault-tolerance, targeting safety-critical applications. We demonstrate the proposed methodology on a SANN system implemented on Xilinx Artix-7 FPGA. The proposed architecture has minimal hardware footprints, power dissipation profile and real-time computational capability, enhancing its usability in constrained applications.

AB - Spike-based brain-inspired systems have shown an immense capability to achieve internal stability, widely referred to as homeostasis. This ability enrols them as the best candidate for next-generation computational neuroscience as they bridge the gap between neuroscience and machine learning. Spiking Neural Networks (SNN), a third generation Artificial Neural Network (ANN), which operates using discrete events of spikes, contributes to a category of biologically-realistic models of neurons to carry out computations. Spiking Astrocyte-Neuron Networks (SANN) have a characteristic attribute homologous to brain self-repair. Although SNNs are more powerful in theory than 2nd generation ANNs, they are not widely in use as their implementations on normal hardware are computationally-intensive. On the contrary, due to the capability of modern hardware such as FPGAs, which operates in MHz and GHz range, facilitates real-time and faster-than-real-time simulations of SNNs. In this work, we overcome the computational overhead of the SNNs using the benefits of real-time hardware computations, utilizing time-multiplexing to design a Self-rePairing spiking Astrocyte Neural NEtwoRk (SPANNER) chip, generic to users' choice of task, emphasizing fault-tolerance, targeting safety-critical applications. We demonstrate the proposed methodology on a SANN system implemented on Xilinx Artix-7 FPGA. The proposed architecture has minimal hardware footprints, power dissipation profile and real-time computational capability, enhancing its usability in constrained applications.

KW - Astrocytes

KW - Bio-inspired Engineering

KW - Fault Tolerance

KW - FPGA

KW - Neuromorphic Computing

KW - Self-Repair

KW - Spiking Neural Networks

KW - Time Multiplexing

UR - http://www.scopus.com/inward/record.url?scp=85062775214&partnerID=8YFLogxK

U2 - 10.1109/SSCI.2018.8628710

DO - 10.1109/SSCI.2018.8628710

M3 - Conference Proceeding (Non-Journal item)

AN - SCOPUS:85062775214

T3 - Proceedings of the 2018 IEEE Symposium Series on Computational Intelligence, SSCI 2018

SP - 1076

EP - 1083

BT - Proceedings of the 2018 IEEE Symposium Series on Computational Intelligence, SSCI 2018

A2 - Sundaram, Suresh

PB - IEEE Press

T2 - 8th IEEE Symposium Series on Computational Intelligence, SSCI 2018

Y2 - 18 November 2018 through 21 November 2018

ER -

Johnson AP, Liu J, Millard AG, Karim S, Tyrrell AM, Harkin J et al. Time-multiplexed System-on-Chip using Fault-tolerant Astrocyte-Neuron Networks. Yn Sundaram S, golygydd, Proceedings of the 2018 IEEE Symposium Series on Computational Intelligence, SSCI 2018. IEEE Press. 2018. t. 1076-1083. 8628710. (Proceedings of the 2018 IEEE Symposium Series on Computational Intelligence, SSCI 2018). doi: 10.1109/SSCI.2018.8628710

Time-multiplexed System-on-Chip using Fault-tolerant Astrocyte-Neuron Networks

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