Title :
Robust SEU Mitigation of 32 nm Dual Redundant Flip-Flops Through Interleaving and Sensitive Node-Pair Spacing
Author :
Cabanas-Holmen, M. ; Cannon, E.H. ; Rabaa, Salim ; Amort, T. ; Ballast, J. ; Carson, Mike ; Lam, D. ; Brees, R.
Author_Institution :
Boeing Co., Seattle, WA, USA
Abstract :
We introduce the 32 nm SOI Boeing Interleaved Flip-Flop, which is based on the DICE topology with additional RHBD layout enhancements. Sensitive node pairs were separated by interleaving elements of the flip-flop cell, to attain the required SEU performance while minimizing the area, speed and power impact. The Boeing Interleaved Flip-Flop takes advantage of the reduced charge sharing inherent to an SOI technology to maintain a two order of magnitude SEU improvement relative to the unhardened flip-flop, which corresponds to more than an order of magnitude SEU rate reduction compared to our 90 nm DICE.
Keywords :
flip-flops; radiation hardening (electronics); DICE topology; RHBD layout enhancements; SOI Boeing interleaved flip-flop; dual redundant flip-flops; reduced charge sharing; robust SEU mitigation; sensitive node pairs; sensitive node-pair spacing; single event upset; size 32 nm; size 90 nm; CMOS integrated circuits; Flip-flops; Radiation effects; Shift registers; Single event upsets; Heavy ion radiation effects; radiation effects; single event upset;
Journal_Title :
Nuclear Science, IEEE Transactions on
DOI :
10.1109/TNS.2013.2288090
