The original paper is in English. Non-English content has been machine-translated and may contain typographical errors or mistranslations. ex. Some numerals are expressed as "XNUMX".
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The original paper is in English. Non-English content has been machine-translated and may contain typographical errors or mistranslations. Copyrights notice
A escala de tensão adaptativa é uma abordagem promissora para superar a variabilidade de fabricação, a flutuação ambiental dinâmica e o envelhecimento. Este artigo se concentra no escalonamento de tensão adaptativo baseado em previsão de erros (EP-AVS) e propõe uma metodologia de projeto consciente do tempo médio até a falha (MTTF) para circuitos EP-AVS. As principais contribuições deste trabalho incluem (1) otimização do circuito com escala de tensão e da lógica de controle de tensão, e (2) avaliação quantitativa da economia de energia para MTTF praticamente longo. Os resultados experimentais mostram que a metodologia de projeto EP-AVS proposta atinge 38.0% de economia de energia enquanto satisfaz o MTTF alvo.
Yutaka MASUDA
Osaka University
Masanori HASHIMOTO
Osaka University
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Yutaka MASUDA, Masanori HASHIMOTO, "MTTF-Aware Design Methodology of Adaptively Voltage Scaled Circuit with Timing Error Predictive Flip-Flop" in IEICE TRANSACTIONS on Fundamentals,
vol. E102-A, no. 7, pp. 867-877, July 2019, doi: 10.1587/transfun.E102.A.867.
Abstract: Adaptive voltage scaling is a promising approach to overcome manufacturing variability, dynamic environmental fluctuation, and aging. This paper focuses on error prediction based adaptive voltage scaling (EP-AVS) and proposes a mean time to failure (MTTF) aware design methodology for EP-AVS circuits. Main contributions of this work include (1) optimization of both voltage-scaled circuit and voltage control logic, and (2) quantitative evaluation of power saving for practically long MTTF. Experimental results show that the proposed EP-AVS design methodology achieves 38.0% power saving while satisfying given target MTTF.
URL: https://global.ieice.org/en_transactions/fundamentals/10.1587/transfun.E102.A.867/_p
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@ARTICLE{e102-a_7_867,
author={Yutaka MASUDA, Masanori HASHIMOTO, },
journal={IEICE TRANSACTIONS on Fundamentals},
title={MTTF-Aware Design Methodology of Adaptively Voltage Scaled Circuit with Timing Error Predictive Flip-Flop},
year={2019},
volume={E102-A},
number={7},
pages={867-877},
abstract={Adaptive voltage scaling is a promising approach to overcome manufacturing variability, dynamic environmental fluctuation, and aging. This paper focuses on error prediction based adaptive voltage scaling (EP-AVS) and proposes a mean time to failure (MTTF) aware design methodology for EP-AVS circuits. Main contributions of this work include (1) optimization of both voltage-scaled circuit and voltage control logic, and (2) quantitative evaluation of power saving for practically long MTTF. Experimental results show that the proposed EP-AVS design methodology achieves 38.0% power saving while satisfying given target MTTF.},
keywords={},
doi={10.1587/transfun.E102.A.867},
ISSN={1745-1337},
month={July},}
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TY - JOUR
TI - MTTF-Aware Design Methodology of Adaptively Voltage Scaled Circuit with Timing Error Predictive Flip-Flop
T2 - IEICE TRANSACTIONS on Fundamentals
SP - 867
EP - 877
AU - Yutaka MASUDA
AU - Masanori HASHIMOTO
PY - 2019
DO - 10.1587/transfun.E102.A.867
JO - IEICE TRANSACTIONS on Fundamentals
SN - 1745-1337
VL - E102-A
IS - 7
JA - IEICE TRANSACTIONS on Fundamentals
Y1 - July 2019
AB - Adaptive voltage scaling is a promising approach to overcome manufacturing variability, dynamic environmental fluctuation, and aging. This paper focuses on error prediction based adaptive voltage scaling (EP-AVS) and proposes a mean time to failure (MTTF) aware design methodology for EP-AVS circuits. Main contributions of this work include (1) optimization of both voltage-scaled circuit and voltage control logic, and (2) quantitative evaluation of power saving for practically long MTTF. Experimental results show that the proposed EP-AVS design methodology achieves 38.0% power saving while satisfying given target MTTF.
ER -