An Area-Efficient 65 nm Radiation-Hard Dual-Modular Flip-Flop to Avoid Multiple Cell Upsets

An Area-Efficient 65 nm Radiation-Hard Dual-Modular Flip-Flop to Avoid Multiple Cell Upsets

A layout structure to avoid upsets due to Multiple Cell Upsets (MCUs) is proposed for rad-hard dual-modular Flip-Flops (FFs) called BCDMR (Bistable Cross-coupled Dual-Modular Redundancy) by separating critical components. We have fabricated a 65 nm chip including 30 kbit dual-modular FF arrays on tw...

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Veröffentlicht in:IEEE transactions on nuclear science 2011-12, Vol.58 (6), p.3053-3059
Hauptverfasser: Yamamoto, R., Hamanaka, C., Furuta, J., Kobayashi, K., Onodera, H.
Format: Artikel
Sprache:eng
Schlagworte:
65 nm bulk CMOS
Arrays
bi-stable cross-coupled dual-modular (BCDMR)
built-in soft-error resilience (BISER)
Chip formation
CMOS technology
dual-interlocked storage cell (DICE)
Elevated
Errors
flip-flop
Flip-flops
Layout
multiple cell upset (MCU)
Neutron irradiation
Radiation hardening
radiation-hard design
Redundancy
Single event upset
Soft errors
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Zusammenfassung:A layout structure to avoid upsets due to Multiple Cell Upsets (MCUs) is proposed for rad-hard dual-modular Flip-Flops (FFs) called BCDMR (Bistable Cross-coupled Dual-Modular Redundancy) by separating critical components. We have fabricated a 65 nm chip including 30 kbit dual-modular FF arrays on twin-well and triple-well structures. High-energy broad-spectrum neutron irradiations reveal that no soft error is observed up to 100 MHz in the twin-well, but some errors are observed in the triple well. The triple-well structure is sensitive to MCUs because the p-well potential can be easily elevated.
ISSN:0018-9499
1558-1578
DOI:10.1109/TNS.2011.2169457