Reliability Physics and Engineering Time-To-Failure Modeling /

• Main Author: McPherson, J. W. (Author)
• Corporate Author: SpringerLink (Online service)
• Format: Electronic
• Language: English
• Published: Heidelberg : Springer International Publishing : Imprint: Springer, 2013.
• Edition: 2nd ed. 2013.
• Subjects: Engineering.; Mathematical statistics.; System safety.; Electronics.; Electronics and Microelectronics, Instrumentation.; Quality Control, Reliability, Safety and Risk.; Statistical Theory and Methods.; Energy, general.
• Online Access: https://ezaccess.library.uitm.edu.my/login?url=http://dx.doi.org/10.1007/978-3-319-00122-7

Reliability Physics and Engineering provides critically important information that is needed for designing and building reliable cost-effective products. Key features include: ʺ Materials/Device Degradation ʺ Degradation Kinetics ʺ Time-To-Failure Modeling ʺ Statistical Tool...

Table of Contents:

• Introduction
• Materials and Device Degradation
• From Material/Device Degradation to Time-To-Failure
• Time-To-Failure Modeling
• Gaussian Statistics <U+0013> An Overview
• Time-To-Failure Statistics
• Failure Rate Modeling
• Accelerated Degradation
• Acceleration Factor Modeling
• Ramp-To-Failure Testing
• Time-To-Failure Models for Selected Failure Mechanisms in Integrated Circuits Breakdown (TDDB)
• Time-To-Failure Models for Selected Failure Mechanisms In Mechanical Engineering
• Conversion of Dynamical Stresses Into Effective Static Values
• Increasing the Reliability of Device/Product Designs
• Screening
• Heat Generation and Dissipation
• Sampling Plans and Confidence Intervals
• Appendix A: Useful Conversion Factors
• Appendix B: Useful Physical Constants
• Appendix C: Useful Rough Rules-Of-Thumb
• Appendix D: Useful Mathematical Expressions
• Appendix E: Useful Differentials and Definite Integrals
• Appendix F: Free-Energy
• Appendix G: t(1-ł/2,ư) Distribution Values
• Appendix H: ß2(P,ư) Distribution Values
• Index.