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Design of high-throughput Inter-PE communication with application-level flow control protocol for many-core architectures

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Jing-Jia LiouAuthors Info & Claims

MES '13: Proceedings of the First International Workshop on Many-core Embedded Systems

Pages 41 - 44

https://doi.org/10.1145/2489068.2489074

Published: 24 June 2013 Publication History

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Abstract

With current trend of increasing the number processing elements (PEs) on a single chip, on-chip network provides a fast and reliable interconnect technology for highly parallel applications. Yet, the end-to-end data throughput at software layer on a NoC (Network-on-Chip) platform often cannot match the hardware native speed without an efficient hardware/software interface. In this paper, we present a high-throughput PE-to-PE communication unit with a corresponding driver layer on NoC-based many-core architectures. The proposed communication unit with application-level flow control can handle complicated inter-PE communication for practical parallel applications. The maximum throughput of a unidirectional transmission with flow control protocol at application-level is 2687.3 Mbps (normalized at operating frequency of 100MHz), where the native NoC speed is 3200 Mbps. As a comparison, a software-based protocol is only rated at 148.5 Mbps. The communication unit is also area-efficient at only 19.2K gates, which is roughly 3.2% of a single in-order RISC-based PE.

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Cited By

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Huang CKuan-Chun Tasi Jun-Shen Lin Hsiao-Wei Chien (2015)Application-level embedded communication tracer for many-core systemsThe 20th Asia and South Pacific Design Automation Conference10.1109/ASPDAC.2015.7059109(803-808)Online publication date: Jan-2015
https://doi.org/10.1109/ASPDAC.2015.7059109
Hsiao-Wei Chien Lai JChao-Chieh Wu Huang CHsu TLiou J(2015)Design of a scalable many-core processor for embedded applicationsThe 20th Asia and South Pacific Design Automation Conference10.1109/ASPDAC.2015.7058928(24-25)Online publication date: Jan-2015
https://doi.org/10.1109/ASPDAC.2015.7058928

Index Terms

Design of high-throughput Inter-PE communication with application-level flow control protocol for many-core architectures
1. Hardware
  1. Very large scale integration design
    1. VLSI system specification and constraints

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Information

Published In

MES '13: Proceedings of the First International Workshop on Many-core Embedded Systems

June 2013

71 pages

ISBN:9781450320634

DOI:10.1145/2489068

General Chairs:
Masoud Daneshtalab
University of Turku, Finland
,
Ahmed Hemani
Royal Institute of Technology, Sweden
,
Maurizio Palesi
Kore University, Italy

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Association for Computing Machinery

New York, NY, United States

Publication History

Published: 24 June 2013

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MES '13

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Univ. Turku

MES '13: International Workshop on Many-Core Embedded Systems

June 24, 2013

Tel-Aviv, Israel

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MES '13 Paper Acceptance Rate 5 of 21 submissions, 24%;

Overall Acceptance Rate 5 of 21 submissions, 24%

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Cited By

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Huang CKuan-Chun Tasi Jun-Shen Lin Hsiao-Wei Chien (2015)Application-level embedded communication tracer for many-core systemsThe 20th Asia and South Pacific Design Automation Conference10.1109/ASPDAC.2015.7059109(803-808)Online publication date: Jan-2015
https://doi.org/10.1109/ASPDAC.2015.7059109
Hsiao-Wei Chien Lai JChao-Chieh Wu Huang CHsu TLiou J(2015)Design of a scalable many-core processor for embedded applicationsThe 20th Asia and South Pacific Design Automation Conference10.1109/ASPDAC.2015.7058928(24-25)Online publication date: Jan-2015
https://doi.org/10.1109/ASPDAC.2015.7058928

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Index Terms

Recommendations

Automatic SoC design flow on many-core processors: a software hardware co-design approach for FPGAs

Scaling high-performance interconnect architectures to many-core systems

Off-chip communication architectures for high throughput network processors