Robust Sequential Circuits Design Technique for Low Voltage and High Noise Scenarios

Robust Sequential Circuits Design Technique for Low Voltage and High Noise Scenarios

All electronic processing components in future deep nanotechnologies will exhibit high noise level and/or low S/N ratios because of the extreme voltage reduction and the nearly erratic nature of such devices. Systems implemented with these devices would exhibit a high probability to fail, causing an...

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Main Authors: Garcia-Leyva Lancelot, Rivera-Dueñas Juan, Calomarde Antonio, Moll Francesc, Rubio Antonio
Format: Article
Language:English
Published: EDP Sciences 2016-01-01
Series:MATEC Web of Conferences
Online Access:http://dx.doi.org/10.1051/matecconf/20164202003
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spelling doaj-061fbff971c841849b8ec7bb0f92716e2021-02-02T03:55:14ZengEDP SciencesMATEC Web of Conferences2261-236X2016-01-01420200310.1051/matecconf/20164202003matecconf_iccma2016_02003Robust Sequential Circuits Design Technique for Low Voltage and High Noise ScenariosGarcia-Leyva LancelotRivera-Dueñas Juan0Calomarde Antonio1Moll Francesc2Rubio Antonio3Universidad Nacional Autónoma de MéxicoUniversitat Politecnica de CatalunyaUniversitat Politecnica de CatalunyaUniversitat Politecnica de CatalunyaAll electronic processing components in future deep nanotechnologies will exhibit high noise level and/or low S/N ratios because of the extreme voltage reduction and the nearly erratic nature of such devices. Systems implemented with these devices would exhibit a high probability to fail, causing an unacceptably reduced reliability. In this paper we introduce an innovative input and output data redundancy principle for sequential block circuits, the responsible to keep the state of the system, showing its efficiency in front of other robust technique approaches. The methodology is totally different from the Von Neumann approaches, because element are not replicated N times, but instead, they check the coherence of redundant input data no allowing data propagation in case of discrepancy. This mechanism does not require voting devices.http://dx.doi.org/10.1051/matecconf/20164202003
collection DOAJ
language English
format Article
sources DOAJ
author Garcia-Leyva Lancelot
Rivera-Dueñas Juan
Calomarde Antonio
Moll Francesc
Rubio Antonio
spellingShingle Garcia-Leyva Lancelot
Rivera-Dueñas Juan
Calomarde Antonio
Moll Francesc
Rubio Antonio
Robust Sequential Circuits Design Technique for Low Voltage and High Noise Scenarios
MATEC Web of Conferences
author_facet Garcia-Leyva Lancelot
Rivera-Dueñas Juan
Calomarde Antonio
Moll Francesc
Rubio Antonio
author_sort Garcia-Leyva Lancelot
title Robust Sequential Circuits Design Technique for Low Voltage and High Noise Scenarios
title_short Robust Sequential Circuits Design Technique for Low Voltage and High Noise Scenarios
title_full Robust Sequential Circuits Design Technique for Low Voltage and High Noise Scenarios
title_fullStr Robust Sequential Circuits Design Technique for Low Voltage and High Noise Scenarios
title_full_unstemmed Robust Sequential Circuits Design Technique for Low Voltage and High Noise Scenarios
title_sort robust sequential circuits design technique for low voltage and high noise scenarios
publisher EDP Sciences
series MATEC Web of Conferences
issn 2261-236X
publishDate 2016-01-01
description All electronic processing components in future deep nanotechnologies will exhibit high noise level and/or low S/N ratios because of the extreme voltage reduction and the nearly erratic nature of such devices. Systems implemented with these devices would exhibit a high probability to fail, causing an unacceptably reduced reliability. In this paper we introduce an innovative input and output data redundancy principle for sequential block circuits, the responsible to keep the state of the system, showing its efficiency in front of other robust technique approaches. The methodology is totally different from the Von Neumann approaches, because element are not replicated N times, but instead, they check the coherence of redundant input data no allowing data propagation in case of discrepancy. This mechanism does not require voting devices.
url http://dx.doi.org/10.1051/matecconf/20164202003
work_keys_str_mv AT garcialeyvalancelot robustsequentialcircuitsdesigntechniqueforlowvoltageandhighnoisescenarios
AT riveraduenasjuan robustsequentialcircuitsdesigntechniqueforlowvoltageandhighnoisescenarios
AT calomardeantonio robustsequentialcircuitsdesigntechniqueforlowvoltageandhighnoisescenarios
AT mollfrancesc robustsequentialcircuitsdesigntechniqueforlowvoltageandhighnoisescenarios
AT rubioantonio robustsequentialcircuitsdesigntechniqueforlowvoltageandhighnoisescenarios
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