Simulation of proton-induced energy deposition in integrated circuits

Author

Fernald, Kenneth W. ; Kerns, Sherra E.

Volume

35

Issue

1

fYear

1988

Firstpage

981

Lastpage

986

Abstract

A time-efficient simulation technique was developed for modeling the energy deposition by incident protons in modern integrated circuits. To avoid the excessive computer time required by many proton-effects simulators, a stochastic method was chosen to model the various physical effects responsible for energy deposition by incident protons. Using probability density functions to describe the nuclear reactions responsible for most proton-induced memory upsets, the simulator determines the probability of a proton hit depositing the energy necessary for circuit destabilization. This factor is combined with various circuit parameters to determine the expected error-rate in a given proton environment. An analysis of transient or dose-rate effects is also performed. A comparison to experimental energy-disposition data proves the simulator to be quite accurate for predicting the expected number of events in certain integrated circuits.<>

Keywords

hybrid integrated circuits; monolithic integrated circuits; proton effects; circuit destabilization; dose-rate effects; energy deposition; incident protons; integrated circuits; nuclear reactions; probability density functions; proton-induced energy deposition; proton-induced memory upsets; stochastic method; time-efficient simulation technique; Circuit simulation; Computational modeling; Computer simulation; Integrated circuit modeling; Performance analysis; Physics computing; Probability density function; Protons; Stochastic processes; Transient analysis;

fLanguage

English

Journal_Title

Nuclear Science, IEEE Transactions on

Publisher

ieee

ISSN

0018-9499

Type

jour

DOI

10.1109/23.12869

Filename

12869