Large-scale on-chip dynamic programming network inferences using moderated inter-core communication

Andrew Mundy; Terrence Mak; Alex Yakovlev; Simon Davidson; Steve Furber

doi:10.1109/ACSD.2012.12

Large-scale on-chip dynamic programming network inferences using moderated inter-core communication

Andrew Mundy, Terrence Mak, Alex Yakovlev, Simon Davidson, Steve Furber

Advanced Processor Technology

Research output: Chapter in Book/Conference proceeding › Conference contribution › peer-review

Abstract

The analysis of large scale, complex networks using dynamic programming is of great use in many scientific and engineering disciplines. Current applications often require the analysis of scale-free networks with many millions of nodes and edges; presenting a huge computational challenge. Employing a distributed networks-on-chip infrastructure presents a unique opportunity of delivering power efficient and massive parallel accelerations. However, bursting and asymmetric communications across cores could create instant network saturation and lead to packet loss and performance degradation. In this paper, we present a moderated communication methodology that enables a balanced channel usage and network topological adaptation for improved performance. A novel analytical communication model for NoC is developed and leads to a theoretical bound of the on-chip communication cost estimate. Performances of the many-core computation and the proposed methods are rigorously evaluated using the real 18-core SpiNNaker chip. We demonstrate a 10x speed-up in analysis convergence and a 42% reduction in instantaneous Packet Injection Rate based on benchmark networks. © 2012 IEEE.

Original language	English
Title of host publication	Proceedings - International Conference on Application of Concurrency to System Design, ACSD\|Proc. Int. Conf. Appl. Concurrency Syst. Des. ACSD
Publisher	IEEE
Pages	62-71
Number of pages	9
ISBN (Print)	9780769547091
DOIs	https://doi.org/10.1109/ACSD.2012.12
Publication status	Published - 2012
Event	2012 12th International Conference on Application of Concurrency to System Design, ACSD 2012 - Hamburg Duration: 1 Jul 2012 → …

Conference

Conference	2012 12th International Conference on Application of Concurrency to System Design, ACSD 2012
City	Hamburg
Period	1/07/12 → …

Keywords

Algorithm design and analysis , Approximation algorithms , Complexity theory
Complexity theory , Computational efficiency , Convergence , Dynamic programming , Educational institutions

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10.1109/ACSD.2012.12

Cite this

Mundy, A., Mak, T., Yakovlev, A., Davidson, S., & Furber, S. (2012). Large-scale on-chip dynamic programming network inferences using moderated inter-core communication. In Proceedings - International Conference on Application of Concurrency to System Design, ACSD|Proc. Int. Conf. Appl. Concurrency Syst. Des. ACSD (pp. 62-71). IEEE. https://doi.org/10.1109/ACSD.2012.12

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title = "Large-scale on-chip dynamic programming network inferences using moderated inter-core communication",

abstract = "The analysis of large scale, complex networks using dynamic programming is of great use in many scientific and engineering disciplines. Current applications often require the analysis of scale-free networks with many millions of nodes and edges; presenting a huge computational challenge. Employing a distributed networks-on-chip infrastructure presents a unique opportunity of delivering power efficient and massive parallel accelerations. However, bursting and asymmetric communications across cores could create instant network saturation and lead to packet loss and performance degradation. In this paper, we present a moderated communication methodology that enables a balanced channel usage and network topological adaptation for improved performance. A novel analytical communication model for NoC is developed and leads to a theoretical bound of the on-chip communication cost estimate. Performances of the many-core computation and the proposed methods are rigorously evaluated using the real 18-core SpiNNaker chip. We demonstrate a 10x speed-up in analysis convergence and a 42% reduction in instantaneous Packet Injection Rate based on benchmark networks. {\textcopyright} 2012 IEEE.",

keywords = "Algorithm design and analysis , Approximation algorithms , Complexity theory, Complexity theory , Computational efficiency , Convergence , Dynamic programming , Educational institutions",

author = "Andrew Mundy and Terrence Mak and Alex Yakovlev and Simon Davidson and Steve Furber",

year = "2012",

doi = "10.1109/ACSD.2012.12",

language = "English",

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pages = "62--71",

booktitle = "Proceedings - International Conference on Application of Concurrency to System Design, ACSD|Proc. Int. Conf. Appl. Concurrency Syst. Des. ACSD",

publisher = "IEEE",

address = "United States",

note = "2012 12th International Conference on Application of Concurrency to System Design, ACSD 2012 ; Conference date: 01-07-2012",

}

Mundy, A, Mak, T, Yakovlev, A, Davidson, S & Furber, S 2012, Large-scale on-chip dynamic programming network inferences using moderated inter-core communication. in Proceedings - International Conference on Application of Concurrency to System Design, ACSD|Proc. Int. Conf. Appl. Concurrency Syst. Des. ACSD. IEEE, pp. 62-71, 2012 12th International Conference on Application of Concurrency to System Design, ACSD 2012, Hamburg, 1/07/12. https://doi.org/10.1109/ACSD.2012.12

Large-scale on-chip dynamic programming network inferences using moderated inter-core communication. / Mundy, Andrew; Mak, Terrence; Yakovlev, Alex et al.
Proceedings - International Conference on Application of Concurrency to System Design, ACSD|Proc. Int. Conf. Appl. Concurrency Syst. Des. ACSD. IEEE, 2012. p. 62-71.

Research output: Chapter in Book/Conference proceeding › Conference contribution › peer-review

TY - GEN

T1 - Large-scale on-chip dynamic programming network inferences using moderated inter-core communication

AU - Mundy, Andrew

AU - Mak, Terrence

AU - Yakovlev, Alex

AU - Davidson, Simon

AU - Furber, Steve

PY - 2012

Y1 - 2012

N2 - The analysis of large scale, complex networks using dynamic programming is of great use in many scientific and engineering disciplines. Current applications often require the analysis of scale-free networks with many millions of nodes and edges; presenting a huge computational challenge. Employing a distributed networks-on-chip infrastructure presents a unique opportunity of delivering power efficient and massive parallel accelerations. However, bursting and asymmetric communications across cores could create instant network saturation and lead to packet loss and performance degradation. In this paper, we present a moderated communication methodology that enables a balanced channel usage and network topological adaptation for improved performance. A novel analytical communication model for NoC is developed and leads to a theoretical bound of the on-chip communication cost estimate. Performances of the many-core computation and the proposed methods are rigorously evaluated using the real 18-core SpiNNaker chip. We demonstrate a 10x speed-up in analysis convergence and a 42% reduction in instantaneous Packet Injection Rate based on benchmark networks. © 2012 IEEE.

AB - The analysis of large scale, complex networks using dynamic programming is of great use in many scientific and engineering disciplines. Current applications often require the analysis of scale-free networks with many millions of nodes and edges; presenting a huge computational challenge. Employing a distributed networks-on-chip infrastructure presents a unique opportunity of delivering power efficient and massive parallel accelerations. However, bursting and asymmetric communications across cores could create instant network saturation and lead to packet loss and performance degradation. In this paper, we present a moderated communication methodology that enables a balanced channel usage and network topological adaptation for improved performance. A novel analytical communication model for NoC is developed and leads to a theoretical bound of the on-chip communication cost estimate. Performances of the many-core computation and the proposed methods are rigorously evaluated using the real 18-core SpiNNaker chip. We demonstrate a 10x speed-up in analysis convergence and a 42% reduction in instantaneous Packet Injection Rate based on benchmark networks. © 2012 IEEE.

KW - Algorithm design and analysis , Approximation algorithms , Complexity theory

KW - Complexity theory , Computational efficiency , Convergence , Dynamic programming , Educational institutions

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BT - Proceedings - International Conference on Application of Concurrency to System Design, ACSD|Proc. Int. Conf. Appl. Concurrency Syst. Des. ACSD

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T2 - 2012 12th International Conference on Application of Concurrency to System Design, ACSD 2012

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ER -

Large-scale on-chip dynamic programming network inferences using moderated inter-core communication

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