Dependence of Cell Distance and Well-Contact Density on MCU Rates by Device Simulations and Neutron Experiments in a 65-nm Bulk Process

Dependence of Cell Distance and Well-Contact Density on MCU Rates by Device Simulations and Neutron Experiments in a 65-nm Bulk Process

Technology scaling increases the role of charge sharing and bipolar effect with respect to multiple cell upset. We analyze the contributions of cell distance and well-contact density to suppress MCU by device-level simulations and neutron experiments. Device simulation results reveal that the ratio...

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Veröffentlicht in:IEEE transactions on nuclear science 2014-08, Vol.61 (4), p.1583-1589
Hauptverfasser: Kuiyuan Zhang, Furuta, Jun, Kobayashi, Kazutoshi, Onodera, Hidetoshi
Format: Artikel
Sprache:eng
Schlagworte:
Bulk density
Charge
Density
Device-stimulation
Devices
Electric potential
Integrated circuit modeling
Inverters
Latches
Layout
MCU
neutron irradiation
Neutrons
parasitic bipolar effect
Redundant
Shift registers
Simulation
soft error
Transaction processing
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Zusammenfassung:Technology scaling increases the role of charge sharing and bipolar effect with respect to multiple cell upset. We analyze the contributions of cell distance and well-contact density to suppress MCU by device-level simulations and neutron experiments. Device simulation results reveal that the ratio of MCU to SEU exponentially decreases by increasing the distance between redundant latches. MCU is suppressed when well contacts are placed between redundant latches. Experimental results also show that the ratio of MCU to SEU exponentially decreases by increasing the distance between cells. MCU is suppressed effectively by increasing the density of well contacts.
ISSN:0018-9499
1558-1578
DOI:10.1109/TNS.2014.2314292