Single Event Effects in Aerospace

Enables readers to better understand, calculate, and manage single event effects
Single event effects, caused by single ionizing particles that penetrate sensitive nodes within an electronic device, can lead to anything from annoying system responses to catastrophic system failures. As electronic components continue to become smaller and smaller due to advances in miniaturization, electronic components designed for avionics are increasingly susceptible to these single event phenomena. With this book in hand, readers learn the core concepts needed to understand, predict, and manage disruptive and potentially damaging single event effects.
Setting the foundation, the book begins with a discussion of the radiation environments in space and in the atmosphere. Next, the book draws together and analyzes some thirty years of findings and best practices reported in the literature, exploring such critical topics as:
Design of heavy ion and proton experiments to optimize the data needed for single event predictions
Data qualification and analysis, including multiple bit upset and parametric studies of device sensitivity
Pros and cons of different approaches to heavy ion, proton, and neutron rate predictions
Results of experiments that have tested space predictions
Single Event Effects in Aerospace is recommended for engineers who design or fabricate parts, subsystems, or systems used in avionics, missile, or satellite applications. It not only provides them with a current understanding of single event effects, it also enables them to predict single event rates in aerospace environments in order to make needed design adjustments.

Spis treści:
1. Introduction.
2. Foundation of Single Event Analysis and Prediction.
3. Optimizing Heavy Ion Experiments for Analysis.
4. Optimizing Proton Testing.
5. Data Qualification and Interpretation.
6. Analysis of various types of SEU data.
7. Cosmic Ray Single Event Rate Calculations.
8. Proton Single Event Rate Calculations.
9. Neutron induced upset.
10. Upsets produced by heavy ion nuclear reactions.
11. Samples of Heavy Ion Rate Prediction.
12. Samples of Proton rate predictions.
13. Combined Environments.
14. Samples of Solar events and extreme situations.
15. Upset Rates in Neutral Particle Beam (NPB) environments.
16. Predictions and Observations of SEU Rates in Space.
17. Limitations of the IRPP approach.
18. Appendices.
19. References.

Nota biograficzna:
EDWARD PETERSEN, PhD, worked for the Naval Research Laboratory from 1969 to 1993. Since then, he has served as a consultant. Dr. Petersen′s research has focused on estimating upset rates for satellite systems. His work has shown that measurements of space upset rates are consistent with predictions based on laboratory experiments. He has authored or coauthored sixty papers on radiation effects, the majority dealing with single event effects. An IEEE Fellow, Dr. Petersen was the recipient of the IEEE Nuclear and Plasma Sciences Society Radiation Effects Award.

Okładka tylna:
Enables readers to better understand, calculate, and manage single event effects
Single event effects, caused by single ionizing particles that penetrate sensitive nodes within an electronic device, can lead to anything from annoying system responses to catastrophic system failures. As electronic components continue to become smaller and smaller due to advances in miniaturization, electronic components designed for avionics are increasingly susceptible to these single event phenomena. With this book in hand, readers learn the core concepts needed to understand, predict, and manage disruptive and potentially damaging single event effects.
Setting the foundation, the book begins with a discussion of the radiation environments in space and in the atmosphere. Next, the book draws together and analyzes some thirty years of findings and best practices reported in the literature, exploring such critical topics as:
Design of heavy ion and proton experiments to optimize the data needed for single event predictions
Data qualification and analysis, including multiple bit upset and parametric studies of device sensitivity
Pros and cons of different approaches to heavy ion, proton, and neutron rate predictions
Results of experiments that have tested space predictions
Single Event Effects in Aerospace is recommended for engineers who design or fabricate parts, subsystems, or systems used in avionics, missile, or satellite applications. It not only provides them with a current understanding of single event effects, it also enables them to predict single event rates in aerospace environments in order to make needed design adjustments.