A resilient 2-D waveguide communication fabric for hybrid wired-wireless NoC design
A resilient 2-D waveguide communication fabric for hybrid wired-wireless NoC design
Hybrid wired-wireless Network-on-Chip (WiNoC) has emerged as an alternative solution to the poor scalability and performance issues of conventional wireline NoC design for future System-on-Chip (SoC). Existing feasible wireless solution for WiNoCs in the form of millimeter wave (mm-Wave) relies on free space signal radiation which has high power dissipation with high degradation rate in the signal strength per transmission distance. Moreover, over the lossy wireless medium, combining wireless and wireline channels drastically reduces the total reliability of the communication fabric. Surface wave has been proposed as an alternative wireless technology for low power on-chip communication. With the right design considerations, the reliability and performance benefits of the surface wave channel could be extended. In this paper, we propose a surface wave communication fabric for emerging WiNoCs that is able to match the reliability of traditional wireline NoCs. First, we propose a realistic channel model which demonstrates that existing mm-Wave WiNoCs suffers from not only free-space spreading loss (FSSL) but also molecular absorption attenuation (MAA), especially at high frequency band, which reduces the reliability of the system. Consequently, we employ a carefully designed transducer and commercially available thin metal conductor coated with a low cost dielectric material to generate surface wave signals with improved transmission gain. Our experimental results demonstrate that the proposed communication fabric can achieve a 5dB operational bandwidth of about 60GHz around the center frequency (60GHz). By improving the transmission reliability of wireless layer, the proposed communication fabric can improve maximum sustainable load of NoCs by an average of 20:9% and 133:3% compared to existing WiNoCs and wireline NoCs, respectively.
359-373
Opoku Agyeman, M.
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Vien, Q.
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Ahmadinia, Ali
846f0835-a96c-4905-87b2-c03a62d4fad5
Yakovlev, A.
099d96b3-7313-49b4-8a57-4bc04f07064d
Tong, K.
71df51fb-9ee8-44e2-b38e-71a79c633dbb
Mak, T.
0f90ac88-f035-4f92-a62a-7eb92406ea53
1 February 2017
Opoku Agyeman, M.
60f10cc2-b1a8-4d13-b335-8a48ab8ac82b
Vien, Q.
b91735d4-c17d-4d13-baad-ddd6954f57e0
Ahmadinia, Ali
846f0835-a96c-4905-87b2-c03a62d4fad5
Yakovlev, A.
099d96b3-7313-49b4-8a57-4bc04f07064d
Tong, K.
71df51fb-9ee8-44e2-b38e-71a79c633dbb
Mak, T.
0f90ac88-f035-4f92-a62a-7eb92406ea53
Opoku Agyeman, M., Vien, Q., Ahmadinia, Ali, Yakovlev, A., Tong, K. and Mak, T.
(2017)
A resilient 2-D waveguide communication fabric for hybrid wired-wireless NoC design.
IEEE Transactions on Parallel and Distributed Systems, 28 (2), .
(doi:10.1109/TPDS.2016.2575836).
Abstract
Hybrid wired-wireless Network-on-Chip (WiNoC) has emerged as an alternative solution to the poor scalability and performance issues of conventional wireline NoC design for future System-on-Chip (SoC). Existing feasible wireless solution for WiNoCs in the form of millimeter wave (mm-Wave) relies on free space signal radiation which has high power dissipation with high degradation rate in the signal strength per transmission distance. Moreover, over the lossy wireless medium, combining wireless and wireline channels drastically reduces the total reliability of the communication fabric. Surface wave has been proposed as an alternative wireless technology for low power on-chip communication. With the right design considerations, the reliability and performance benefits of the surface wave channel could be extended. In this paper, we propose a surface wave communication fabric for emerging WiNoCs that is able to match the reliability of traditional wireline NoCs. First, we propose a realistic channel model which demonstrates that existing mm-Wave WiNoCs suffers from not only free-space spreading loss (FSSL) but also molecular absorption attenuation (MAA), especially at high frequency band, which reduces the reliability of the system. Consequently, we employ a carefully designed transducer and commercially available thin metal conductor coated with a low cost dielectric material to generate surface wave signals with improved transmission gain. Our experimental results demonstrate that the proposed communication fabric can achieve a 5dB operational bandwidth of about 60GHz around the center frequency (60GHz). By improving the transmission reliability of wireless layer, the proposed communication fabric can improve maximum sustainable load of NoCs by an average of 20:9% and 133:3% compared to existing WiNoCs and wireline NoCs, respectively.
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IEEE_TPDS2016.pdf
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Accepted/In Press date: 3 May 2016
e-pub ahead of print date: 2 June 2016
Published date: 1 February 2017
Organisations:
Electronic & Software Systems
Identifiers
Local EPrints ID: 401849
URI: http://eprints.soton.ac.uk/id/eprint/401849
ISSN: 1045-9219
PURE UUID: 9ca1559f-9d45-4f49-ae19-02742af53abb
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Date deposited: 24 Oct 2016 13:19
Last modified: 15 Mar 2024 02:56
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Contributors
Author:
M. Opoku Agyeman
Author:
Q. Vien
Author:
Ali Ahmadinia
Author:
A. Yakovlev
Author:
K. Tong
Author:
T. Mak
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