Gate-level mitigation techniques for neutron-induced soft error rate

Author

Deogun, Harmander Singh ; Sylvester, Dennis ; Blaauw, David

Author_Institution

Dept. of Electr. Eng. & Comput. Sci., Michigan Univ., Ann Arbor, MI, USA

fYear

2005

fDate

21-23 March 2005

Firstpage

175

Lastpage

180

Abstract

Neutron-induced single-event upsets have become increasingly problematic in aggressively scaled process technologies due to smaller nodal capacitances and reduced operating voltages. We present a probability-based analysis of neutron strikes on combinational logic chains and investigate techniques to increase circuit robustness in terms of decreasing the probability of upsetting the capturing latch given a particle strike. We show that using a technique of inserting simple cross-coupled inverter pairs on error prone sites, as well as intelligently placing lower V_th devices and readjusting device width, can increase the robustness by nearly 20% thereby increasing the mean time between soft errors by almost 25%. This technique incurs substantially less overhead than traditional redundancy approaches to mitigating soft errors.

Keywords

circuit stability; collision processes; combinational circuits; cosmic ray neutrons; error statistics; integrated circuits; logic gates; probability; aggressively scaled process technologies; capturing latch; combinational logic chains; cosmic rays; cross-coupled inverter pairs; gate-level mitigation techniques; mean time between errors; neutron strikes; neutron-induced soft error rate; nodal capacitance; operating voltages; particle strike; probability-based analysis; redundancy; robustness; single-event upsets; Alpha particles; Capacitance; Circuits; Error analysis; Latches; Logic devices; Neutrons; Robustness; Single event transient; Voltage;

fLanguage

English

Publisher

ieee

Conference_Titel

Quality of Electronic Design, 2005. ISQED 2005. Sixth International Symposium on

Print_ISBN

0-7695-2301-3

Type

conf

DOI

10.1109/ISQED.2005.61

Filename

1410579