Circuit Self-Recovery Experiments in Extreme Environments

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	Similar Articles Articles by Adrian Stoica Articles by Didier Keymeulen Articles by Tughrul Arslan Articles by Vu Duong Articles by Ricardo Zebulum Articles by Ian Ferguson Articles by Xin Guo

2004 NASA/DoD Conference on Evolvable Hardware (EH'04)

Seattle, Washington, USA

June 24-June 26

ISBN: 0-7695-2145-2

	ASCII Text	x
	Adrian Stoica, Didier Keymeulen, Tughrul Arslan, Vu Duong, Ricardo Zebulum, Ian Ferguson, Xin Guo, "Circuit Self-Recovery Experiments in Extreme Environments," Evolvable Hardware, NASA/DoD Conference on, pp. 142, 2004 NASA/DoD Conference on Evolvable Hardware (EH'04), 2004.

	BibTex	x
	@article{ 10.1109/EH.2004.1310823, author = {Adrian Stoica and Didier Keymeulen and Tughrul Arslan and Vu Duong and Ricardo Zebulum and Ian Ferguson and Xin Guo}, title = {Circuit Self-Recovery Experiments in Extreme Environments}, journal ={Evolvable Hardware, NASA/DoD Conference on}, volume = {0}, year = {2004}, isbn = {0-7695-2145-2}, pages = {142}, doi = {http://doi.ieeecomputersociety.org/10.1109/EH.2004.1310823}, publisher = {IEEE Computer Society}, address = {Los Alamitos, CA, USA}, }

	RefWorks Procite/RefMan/Endnote	x
	TY - CONF JO - Evolvable Hardware, NASA/DoD Conference on TI - Circuit Self-Recovery Experiments in Extreme Environments SN - 0-7695-2145-2 SP EP A1 - Adrian Stoica, A1 - Didier Keymeulen, A1 - Tughrul Arslan, A1 - Vu Duong, A1 - Ricardo Zebulum, A1 - Ian Ferguson, A1 - Xin Guo, PY - 2004 KW - null VL - 0 JA - Evolvable Hardware, NASA/DoD Conference on ER -

Adrian Stoica, Jet Propulsion Laboratory, Pasadena, CA

Didier Keymeulen, Jet Propulsion Laboratory, Pasadena, CA

Tughrul Arslan, Edinburgh University, UK

Vu Duong, Jet Propulsion Laboratory, Pasadena, CA

Ricardo Zebulum, Jet Propulsion Laboratory, Pasadena, CA

Ian Ferguson, Jet Propulsion Laboratory, Pasadena, CA

Xin Guo, Chromatech, Alameda, CA

DOI Bookmark: http://doi.ieeecomputersociety.org/10.1109/EH.2004.1310823

Temperature and radiation tolerant electronics, as well as long life survivability are key capabilities required for future NASA missions. Current approaches to electronics for extreme environments focus on component level robustness and hardening. However, current technology can only ensure very limited lifetime in extreme environments. This paper describes novel experiments that allow adaptive in-situ circuit redesign/reconfiguration in extreme temperature and radiation environments. This technology would complement material/device/layout advancements and increase the mission capability to survive harsh environments. The approach is demonstrated on a mixed-signal programmable chip (FPTA-2), which recovers functionality for temperatures reaching 280? C and with tota radiation dose up to 175kRad.

Citation:

Adrian Stoica, Didier Keymeulen, Tughrul Arslan, Vu Duong, Ricardo Zebulum, Ian Ferguson, Xin Guo, "Circuit Self-Recovery Experiments in Extreme Environments," eh, pp.142, 2004 NASA/DoD Conference on Evolvable Hardware (EH'04), 2004

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