Title :
Monte Carlo Simulation of Single Event Effects
Author :
Weller, Robert A. ; Mendenhall, Marcus H. ; Reed, Robert A. ; Schrimpf, Ronald D. ; Warren, Kevin M. ; Sierawski, Brian D. ; Massengill, Lloyd W.
Author_Institution :
Dept. of Electr. Eng. & Comput. Sci., Vanderbilt Univ., Nashville, TN, USA
Abstract :
In this paper, we describe a Monte Carlo approach for estimating the frequency and character of single event effects based on a combination of physical modeling of discrete radiation events, device simulations to estimate charge transport and collection, and circuit simulations to determine the effect of the collected charge. A mathematical analysis of the procedure reveals it to be closely related to the rectangular parallelepiped (RPP) rate prediction method. The results of these simulations show that event-to-event variation may have a significant impact when predicting the single-event rate in advanced spacecraft electronics. Specific criteria for supplementing established RPP-based single event analysis with Monte Carlo computations are discussed.
Keywords :
Monte Carlo methods; circuit simulation; mathematical analysis; radiation effects; space vehicle electronics; Monte Carlo simulation; advanced spacecraft electronics; charge transport; circuit simulations; device simulations; discrete radiation events; mathematical analysis; rectangular parallelepiped rate prediction method; single event effects; Aerospace electronics; Circuit simulation; Computational modeling; Discrete event simulation; Equations; Frequency estimation; Integrated circuit modeling; Mathematical analysis; Mathematical model; Monte Carlo methods; Physics; Prediction methods; Predictive models; Space vehicles; Computer simulation; GEANT; Monte Carlo simulation; computing applications; cosmic rays; radiation transport modeling; single event effects; single event modeling; single event rates; software; space radiation effects;
Journal_Title :
Nuclear Science, IEEE Transactions on
DOI :
10.1109/TNS.2010.2044807
