Contribution of Control Logic Upsets and Multi-Node Charge Collection to Flip-Flop SEU Cross-Section in 40-nm CMOS

Contribution of Control Logic Upsets and Multi-Node Charge Collection to Flip-Flop SEU Cross-Section in 40-nm CMOS

Heavy-ion measurements on 40-nm flip-flops indicate pattern dependence of cross-section resulting from local control logic upsets, such as clock nodes. A Monte-Carlo model of the flip-flop, calibrated to the heavy-ion data, is used to analyze the impact of multi-node charge collection within a flip-...

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Veröffentlicht in:IEEE transactions on nuclear science 2010-12, Vol.57 (6), p.3176-3182
Hauptverfasser: Narasimham, B, Wang, J K, Buer, M, Gorti, R, Chandrasekharan, K, Warren, K M, Sierawski, B D, Schrimpf, R D, Reed, R A, Weller, R A
Format: Artikel
Sprache:eng
Schlagworte:
Calibration
Charge
CMOS
CMOS technology
Collection
Cross sections
Cross-section
flip-flop
Flip-flops
heavy-ion
Logic
Monte Carlo methods
Monte-Carlo
MRED
multi-node charge collection
Single event upset
soft error
Strikes
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Zusammenfassung:Heavy-ion measurements on 40-nm flip-flops indicate pattern dependence of cross-section resulting from local control logic upsets, such as clock nodes. A Monte-Carlo model of the flip-flop, calibrated to the heavy-ion data, is used to analyze the impact of multi-node charge collection within a flip-flop due to a single particle strike. Depending on the nodes that collect charge, multi-node charge collection can either increase or decrease the vulnerability of the cell. For neutrons, the overall effect of such events was found to be a net increase in cross-section by up to 16%.
ISSN:0018-9499
1558-1578
DOI:10.1109/TNS.2010.2081687