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100   $a20101207d2011      uy             0
101 0 $aeng
135   $aur|n|---|||||
181   $ctxt
182   $cc
183   $acr
200 10$aFailure analysis$b[electronic resource] $ea practical guide for manufacturers of electronic components and systems /$fMarius I. Ba?zu, Titu-Marius I. Ba?jenescu
210   $aChichester, West Sussex, U.K. $cWiley$dc2011
215   $a1 online resource (341 p.)
225 1 $aWiley series in quality & reliability engineering
300   $aDescription based upon print version of record.
311   $a0-470-74824-9 
320   $aIncludes bibliographical references and index.
327   $aFAILURE ANALYSIS; Contents; Series Editor's Foreword; Foreword by Dr Craig Hillman; Series Editor's Preface; Preface; About the Authors; 1 Introduction; 1.1 The Three Goals of the Book; 1.2 Historical Perspective; 1.2.1 Reliability Prehistory; 1.2.2 The Birth of Reliability as a Discipline; 1.2.3 Historical Development of Reliability; 1.2.4 Tools for Failure Analysis; 1.3 Terminology; 1.4 State of the Art and Future Trends; 1.4.1 Techniques of Failure Analysis; 1.4.2 Failure Mechanisms; 1.4.3 Models for the Physics-of-Failure; 1.4.4 Future Trends; 1.5 General Plan of the Book; References
327   $a2 Failure Analysis - Why?2.1 Eight Possible Applications; 2.2 Forensic Engineering; 2.2.1 FA at System Level; 2.2.2 FA at Component Level; 2.3 Reliability Modelling; 2.3.1 Economic Benefits of Using Reliability Models; 2.3.2 Reliability of Humans; 2.4 Reverse Engineering; 2.5 Controlling Critical Input Variables; 2.6 Design for Reliability; 2.7 Process Improvement; 2.7.1 Reliability Assurance; 2.8 Saving Money through Early Control; 2.9 A Synergetic Approach; 2.9.1 Synergies of Technological Factors; 2.9.2 Test Structures; 2.9.3 Packaging Reliability
327   $a2.9.4 Synergies of Operational Stress Factors2.9.5 Synergetic Team; References; 3 Failure Analysis - When?; 3.1 Failure Analysis during the Development Cycle; 3.1.1 Concurrent Engineering; 3.1.2 Failure Analysis during the Design Stage; 3.1.3 Virtual Prototyping; 3.1.4 Reliability Testing during the Development Cycle; 3.2 Failure Analysis during Fabrication Preparation; 3.2.1 Reliability Analysis of Materials; 3.2.2 Degradation Phenomena in Polymers used in Electron Components; 3.3 FA during Fabrication; 3.3.1 Manufacturing History; 3.3.2 Reliability Monitoring; 3.3.3 Wafer-Level Reliability
327   $a3.3.4 Yield and Reliability3.3.5 Packaging Reliability; 3.3.6 Improving Batch Reliability: Screening and Burn-In; 3.4 FA after Fabrication; 3.4.1 Standard-Based Testing; 3.4.2 Knowledge-Based Testing; 3.5 FA during Operation; 3.5.1 Failure Types during Operation; 3.5.2 Preventive Maintenance of Electronic Systems; References; 4 Failure Analysis - How?; 4.1 Procedures for Failure Analysis; 4.2 Techniques for Decapsulating the Device and for Sample Preparation; 4.2.1 Decapping Techniques; 4.2.2 Decapsulation Techniques; 4.2.3 Cross-Sectioning; 4.2.4 Focused Ion Beam; 4.2.5 Other Techniques
327   $a4.3 Techniques for Failure Analysis4.3.1 Electrical Techniques; 4.3.2 Optical Microscopy; 4.3.3 Scanning Probe Microscopy (SPM); 4.3.4 Microthermographical Techniques; 4.3.5 Electron Microscopy; 4.3.6 X-Ray Techniques; 4.3.7 Spectroscopic Techniques; 4.3.8 Acoustic Techniques; 4.3.9 Laser Techniques; 4.3.10 Holographic Interferometry; 4.3.11 Emission Microscopy; 4.3.12 Atom Probe; 4.3.13 Neutron Radiography; 4.3.14 Electromagnetic Field Measurements; 4.3.15 Other Techniques; References; 5 Failure Analysis - What?; 5.1 Failure Modes and Mechanisms at Various Process Steps; 5.1.1 Wafer Level
327   $a5.1.2 Packaging
330   $aFailure analysis is the preferred method to investigate product or process reliability and to ensure optimum performance of electrical components and systems. The physics-of-failure approach is the only internationally accepted solution for continuously improving the reliability of materials, devices and processes. The models have been developed from the physical and chemical phenomena that are responsible for degradation or failure of electronic components and materials and now replace popular distribution models for failure mechanisms such as Weibull or lognormal. Reliability engineers nee
410  0$aWiley series in quality and reliability engineering.
606   $aElectronic apparatus and appliances$xReliability
606   $aElectronic systems$xTesting
606   $aSystem failures (Engineering)$xPrevention
615  0$aElectronic apparatus and appliances$xReliability.
615  0$aElectronic systems$xTesting.
615  0$aSystem failures (Engineering)$xPrevention.
676   $a621.381
686   $aTEC032000$2bisacsh
700   $aBa?zu$b M. I$g(Marius I.),$f1948-$0917706
701   $aBa?jenescu$b Titu I.$f1938-$0479747
801  0$bMiAaPQ
801  1$bMiAaPQ
801  2$bMiAaPQ
906   $aBOOK
912   $a9910130867603321
996   $aFailure analysis$92057679
997   $aUNINA