DeSyRe: On-demand adaptive and reconfigurable fault-tolerant SoCs

I. Sourdis; C. Strydis; A. Armato; C. S. Bouganis; B. Falsafi; G. N. Gaydadjiev; S. Isaza; A. Malek; R. Mariani; S. Pagliarini; D. N. Pnevmatikatos; D. K. Pradhan; G. Rauwerda; R. M. Seepers; R. A. Shafik; G. Smaragdos; D. Theodoropoulos; S. Tzilis; M. Vavouras

doi:10.1007/978-3-319-05960-0_34

DeSyRe: On-demand adaptive and reconfigurable fault-tolerant SoCs

I. Sourdis, C. Strydis, A. Armato, C. S. Bouganis, B. Falsafi, G. N. Gaydadjiev, S. Isaza, A. Malek, R. Mariani, S. Pagliarini, D. N. Pnevmatikatos, D. K. Pradhan, G. Rauwerda, R. M. Seepers, R. A. Shafik, G. Smaragdos, D. Theodoropoulos, S. Tzilis, M. Vavouras

Research output: Chapter in Book/Conference proceedings/Edited volume › Conference contribution › Scientific › peer-review

1 Citation (Scopus)

Abstract

The DeSyRe project builds on-demand adaptive, reliable Systems-on-Chips. In response to the current semiconductor technology trends thatmake chips becoming less reliable, DeSyRe describes a newgeneration of by design reliable systems, at a reduced power and performance cost. This is achieved through the following main contributions. DeSyRe defines a fault-tolerant system architecture built out of unreliable components, rather than aiming at totally fault-free and hence more costly chips. In addition, DeSyRe systems are on-demand adaptive to various types and densities of faults, as well as to other system constraints and application requirements. For leveraging on-demand adaptation/customization and reliability at reduced cost, a new dynamically reconfigurable substrate is designed and combined with runtime system software support. The above define a generic and repeatable design framework, which is applied to two medical SoCs with high reliability constraints and diverse performance and power requirements. One of the main goals of the DeSyRe project is to increase the availability of SoC components in the presence of permanents faults, caused at manufacturing time or due to device aging. A mix of coarse- and fine-grain reconfigurable hardware substrate is designed to isolate and bypass faulty component parts. The flexibility provided by the DeSyRe reconfigurable substrate is exploited at runtime by system optimization heuristics,which decide tomodify component configurationwhen a permanent fault is detected, providing graceful degradation.

Original language	English
Title of host publication	Reconfigurable Computing
Subtitle of host publication	Architectures, Tools, and Applications - 10th International Symposium, ARC 2014, Proceedings
Publisher	Springer
Pages	312-317
Number of pages	6
ISBN (Print)	9783319059594
DOIs	https://doi.org/10.1007/978-3-319-05960-0_34
Publication status	Published - 2014
Externally published	Yes
Event	10th International Symposium on Reconfigurable Computing: Architectures, Tools, and Applications, ARC 2014 - Vilamoura, Portugal Duration: 14 Apr 2014 → 16 Apr 2014

Publication series

Name	Lecture Notes in Computer Science (including subseries Lecture Notes in Artificial Intelligence and Lecture Notes in Bioinformatics)
Volume	8405 LNCS
ISSN (Print)	0302-9743
ISSN (Electronic)	1611-3349

Conference

Conference	10th International Symposium on Reconfigurable Computing: Architectures, Tools, and Applications, ARC 2014
Country/Territory	Portugal
City	Vilamoura
Period	14/04/14 → 16/04/14

Access to Document

10.1007/978-3-319-05960-0_34

Cite this

Sourdis, I., Strydis, C., Armato, A., Bouganis, C. S., Falsafi, B., Gaydadjiev, G. N., Isaza, S., Malek, A., Mariani, R., Pagliarini, S., Pnevmatikatos, D. N., Pradhan, D. K., Rauwerda, G., Seepers, R. M., Shafik, R. A., Smaragdos, G., Theodoropoulos, D., Tzilis, S., & Vavouras, M. (2014). DeSyRe: On-demand adaptive and reconfigurable fault-tolerant SoCs. In Reconfigurable Computing: Architectures, Tools, and Applications - 10th International Symposium, ARC 2014, Proceedings (pp. 312-317). (Lecture Notes in Computer Science (including subseries Lecture Notes in Artificial Intelligence and Lecture Notes in Bioinformatics); Vol. 8405 LNCS). Springer. https://doi.org/10.1007/978-3-319-05960-0_34

Sourdis, I. ; Strydis, C. ; Armato, A. et al. / DeSyRe : On-demand adaptive and reconfigurable fault-tolerant SoCs. Reconfigurable Computing: Architectures, Tools, and Applications - 10th International Symposium, ARC 2014, Proceedings. Springer, 2014. pp. 312-317 (Lecture Notes in Computer Science (including subseries Lecture Notes in Artificial Intelligence and Lecture Notes in Bioinformatics)).

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title = "DeSyRe: On-demand adaptive and reconfigurable fault-tolerant SoCs",

abstract = "The DeSyRe project builds on-demand adaptive, reliable Systems-on-Chips. In response to the current semiconductor technology trends thatmake chips becoming less reliable, DeSyRe describes a newgeneration of by design reliable systems, at a reduced power and performance cost. This is achieved through the following main contributions. DeSyRe defines a fault-tolerant system architecture built out of unreliable components, rather than aiming at totally fault-free and hence more costly chips. In addition, DeSyRe systems are on-demand adaptive to various types and densities of faults, as well as to other system constraints and application requirements. For leveraging on-demand adaptation/customization and reliability at reduced cost, a new dynamically reconfigurable substrate is designed and combined with runtime system software support. The above define a generic and repeatable design framework, which is applied to two medical SoCs with high reliability constraints and diverse performance and power requirements. One of the main goals of the DeSyRe project is to increase the availability of SoC components in the presence of permanents faults, caused at manufacturing time or due to device aging. A mix of coarse- and fine-grain reconfigurable hardware substrate is designed to isolate and bypass faulty component parts. The flexibility provided by the DeSyRe reconfigurable substrate is exploited at runtime by system optimization heuristics,which decide tomodify component configurationwhen a permanent fault is detected, providing graceful degradation.",

author = "I. Sourdis and C. Strydis and A. Armato and Bouganis, {C. S.} and B. Falsafi and Gaydadjiev, {G. N.} and S. Isaza and A. Malek and R. Mariani and S. Pagliarini and Pnevmatikatos, {D. N.} and Pradhan, {D. K.} and G. Rauwerda and Seepers, {R. M.} and Shafik, {R. A.} and G. Smaragdos and D. Theodoropoulos and S. Tzilis and M. Vavouras",

year = "2014",

doi = "10.1007/978-3-319-05960-0_34",

language = "English",

isbn = "9783319059594",

series = "Lecture Notes in Computer Science (including subseries Lecture Notes in Artificial Intelligence and Lecture Notes in Bioinformatics)",

publisher = "Springer",

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booktitle = "Reconfigurable Computing",

note = "10th International Symposium on Reconfigurable Computing: Architectures, Tools, and Applications, ARC 2014 ; Conference date: 14-04-2014 Through 16-04-2014",

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Sourdis, I, Strydis, C, Armato, A, Bouganis, CS, Falsafi, B, Gaydadjiev, GN, Isaza, S, Malek, A, Mariani, R, Pagliarini, S, Pnevmatikatos, DN, Pradhan, DK, Rauwerda, G, Seepers, RM, Shafik, RA, Smaragdos, G, Theodoropoulos, D, Tzilis, S & Vavouras, M 2014, DeSyRe: On-demand adaptive and reconfigurable fault-tolerant SoCs. in Reconfigurable Computing: Architectures, Tools, and Applications - 10th International Symposium, ARC 2014, Proceedings. Lecture Notes in Computer Science (including subseries Lecture Notes in Artificial Intelligence and Lecture Notes in Bioinformatics), vol. 8405 LNCS, Springer, pp. 312-317, 10th International Symposium on Reconfigurable Computing: Architectures, Tools, and Applications, ARC 2014, Vilamoura, Portugal, 14/04/14. https://doi.org/10.1007/978-3-319-05960-0_34

DeSyRe: On-demand adaptive and reconfigurable fault-tolerant SoCs. / Sourdis, I.; Strydis, C.; Armato, A. et al.
Reconfigurable Computing: Architectures, Tools, and Applications - 10th International Symposium, ARC 2014, Proceedings. Springer, 2014. p. 312-317 (Lecture Notes in Computer Science (including subseries Lecture Notes in Artificial Intelligence and Lecture Notes in Bioinformatics); Vol. 8405 LNCS).

Research output: Chapter in Book/Conference proceedings/Edited volume › Conference contribution › Scientific › peer-review

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AU - Falsafi, B.

AU - Gaydadjiev, G. N.

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AU - Malek, A.

AU - Mariani, R.

AU - Pagliarini, S.

AU - Pnevmatikatos, D. N.

AU - Pradhan, D. K.

AU - Rauwerda, G.

AU - Seepers, R. M.

AU - Shafik, R. A.

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AB - The DeSyRe project builds on-demand adaptive, reliable Systems-on-Chips. In response to the current semiconductor technology trends thatmake chips becoming less reliable, DeSyRe describes a newgeneration of by design reliable systems, at a reduced power and performance cost. This is achieved through the following main contributions. DeSyRe defines a fault-tolerant system architecture built out of unreliable components, rather than aiming at totally fault-free and hence more costly chips. In addition, DeSyRe systems are on-demand adaptive to various types and densities of faults, as well as to other system constraints and application requirements. For leveraging on-demand adaptation/customization and reliability at reduced cost, a new dynamically reconfigurable substrate is designed and combined with runtime system software support. The above define a generic and repeatable design framework, which is applied to two medical SoCs with high reliability constraints and diverse performance and power requirements. One of the main goals of the DeSyRe project is to increase the availability of SoC components in the presence of permanents faults, caused at manufacturing time or due to device aging. A mix of coarse- and fine-grain reconfigurable hardware substrate is designed to isolate and bypass faulty component parts. The flexibility provided by the DeSyRe reconfigurable substrate is exploited at runtime by system optimization heuristics,which decide tomodify component configurationwhen a permanent fault is detected, providing graceful degradation.

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Sourdis I, Strydis C, Armato A, Bouganis CS, Falsafi B, Gaydadjiev GN et al. DeSyRe: On-demand adaptive and reconfigurable fault-tolerant SoCs. In Reconfigurable Computing: Architectures, Tools, and Applications - 10th International Symposium, ARC 2014, Proceedings. Springer. 2014. p. 312-317. (Lecture Notes in Computer Science (including subseries Lecture Notes in Artificial Intelligence and Lecture Notes in Bioinformatics)). doi: 10.1007/978-3-319-05960-0_34

DeSyRe: On-demand adaptive and reconfigurable fault-tolerant SoCs

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