Design for Reliability (Electronics Handbook Series) [Kindle Edition]

This book is definitely a strong addition to the body of knowledge for Reliability Professionals and for any Company that wants to improve the business competitiveness by improving the product reliability.

The book clearly provides the correct focus on the customer, but it also elaborates on the fact that one customer is the corporate business enterprise.

The book shows the optimum sequence of DfR activities in the development phases. This book also has impressive details for the specific DfR elements. It is also an excellent resource for guidance into specific details.

I like the balance of graphics with text and the graphics added excellent additional understanding.

This is an outstanding Industry leader that has documented the implemented practice in this book.

I did not attempt to verify every mathematical formula.

As one of the authors/editors of this book, let me describe the valuable technical content. First, let me impress upon you that this is a rare practical work in reliability written by members of a highly technical company that apply reliability science every day to products. Thus, academics are stressed only as a tool. Therefore, this book has something for everyone. It starts off with a management perspective on how to organize a reliability program. Chapter 1 - 5 overview a unique stage-gate approach to growing reliability. What tools and building blocks are needed from a management perspective to be world-class. What tests to perform when is also key. This approach assures optimum reliability grow in a commercial atmosphere of on-time reliable product deliveries. The book then evolves technically providing essential engineering topics. Chapter 6 describes key information for performing process reliability studies. Chapter 7, is without question a compact chapter on failure analysis that describes each analysis tool including SEM, SAM, EDS, FTIR, FIB, SIMS, etc. The numerous physics of failure analysis examples in diffusion, corrosion, intermetallics, ESD etc are illustrated with detailed FA images. Then Chapter 8 provides what you need to know for reliability statistics. It covers basic definitions for failure rate, CDF, PDF, the main distributions used (Weibull, lognormal, Exponential, Normal). A well-organized chapter presenting key essential reliability statistics needed in industry. Chapter 9 details accelerated testing, the primary historical equations governing temperature, temperature-humidity, vibration and temperature cycle/shock, and electromigration. It provides common sense guidelines for assessing overstressing. How to use these equations for test planning. Advance topics including Step-stress and how to describe life distributions as a function of stress. Chapter 10 on Accelerated Reliability Growth is fairly unique. What tests do you perform and when, using stage-gate and recent accelerated reliability growth mathematics for planning. Growth can be obtained and assessed in a timely manner. Chapter 11 provides the essential for system reliability. Series, parallel, and n of k subsystems as well as predicting reliability using both Bellcore, and 217 methods are addressed. Chapter 12 is an excellent overview of FMEA. Chapter 13 teaches methods for evaluating product risk and conducting risk program management. Lastly, Chapter 14 is an advanced topic, thermodynamic reliability engineering. No other book teaches thermodynamics and how the 1st and 2nd laws are fundamental to the science for Physics-of-Failure. In no other book can a reader find derivations for accelerated testing time compression expressions in fatigue, temperature-humidity, Miner's rule, and diffusion. Additionally, an advanced Arrhenius kinetic topics on logarithmic-in-time aging are provided. This topic as a seminar received the highest ratings at the 2001 RAMS conference. Thank You - Alec Feinberg.

I originally rated this book poorly, but have since changed my mind upon a re-read. I still cannot recommend it due to the cost; however, the final chapter on Thermodynamic Reliability Engineering provides a good physical basis for the mathematical form of a wide range of descriptive reliability models dealing with failures due to stress cycling (Miner's Rule), humidity aging (Peck), corrosion, diffusion (Arrhenius), and vibration induced fatigue abased on thermodynamic principles. I think it is a chapter that every reliability engineer should read A reasonable knowledge of chemistry (reaction rates, thermodynamics, Gibb's free energy, etc.) and physics would be an asset. . The chapter in on Analytical Physics is a good, but again thin overview. The remaining chapters are just too light on substance and some sections, notably the section on step stress aging, are poorly written. The means for identifying multiple failure modes and the requirements of a consistent shape constant parameter of the statistical model characterizing the failure distribution and different stress is essentially missing. For the mathematics of reliability I would recommend Applied Reliability by Trindade and Tobias, or the NIST Engineering Statistics Handbook online.