Design for Reliability (eBook, ePUB)
Schade – dieser Artikel ist leider ausverkauft. Sobald wir wissen, ob und wann der Artikel wieder verfügbar ist, informieren wir Sie an dieser Stelle.
Design for Reliability (eBook, ePUB)
- Format: ePub
- Merkliste
- Auf die Merkliste
- Bewerten Bewerten
- Teilen
- Produkt teilen
- Produkterinnerung
- Produkterinnerung
Bitte loggen Sie sich zunächst in Ihr Kundenkonto ein oder registrieren Sie sich bei
bücher.de, um das eBook-Abo tolino select nutzen zu können.
Hier können Sie sich einloggen
Hier können Sie sich einloggen
Sie sind bereits eingeloggt. Klicken Sie auf 2. tolino select Abo, um fortzufahren.
Bitte loggen Sie sich zunächst in Ihr Kundenkonto ein oder registrieren Sie sich bei bücher.de, um das eBook-Abo tolino select nutzen zu können.
A unique, design-based approach to reliability engineering Design for Reliability provides engineers and managers with a range of tools and techniques for incorporating reliability into the design process for complex systems. It clearly explains how to design for zero failure of critical system functions, leading to enormous savings in product life-cycle costs and a dramatic improvement in the ability to compete in global markets. Readers will find a wealth of design practices not covered in typical engineering books, allowing them to think outside the box when developing reliability…mehr
- Geräte: eReader
- eBook Hilfe
Andere Kunden interessierten sich auch für
A unique, design-based approach to reliability engineering Design for Reliability provides engineers and managers with a range of tools and techniques for incorporating reliability into the design process for complex systems. It clearly explains how to design for zero failure of critical system functions, leading to enormous savings in product life-cycle costs and a dramatic improvement in the ability to compete in global markets. Readers will find a wealth of design practices not covered in typical engineering books, allowing them to think outside the box when developing reliability requirements. They will learn to address high failure rates associated with systems that are not properly designed for reliability, avoiding expensive and time-consuming engineering changes, such as excessive testing, repairs, maintenance, inspection, and logistics. Special features of this book include: * A unified approach that integrates ideas from computer science and reliability engineering * Techniques applicable to reliability as well as safety, maintainability, system integration, and logistic engineering * Chapters on design for extreme environments, developing reliable software, design for trustworthiness, and HALT influence on design Design for Reliability is a must-have guide for engineers and managers in R&D, product development, reliability engineering, product safety, and quality assurance, as well as anyone who needs to deliver high product performance at a lower cost while minimizing system failure.
Produktdetails
- Produktdetails
- Verlag: John Wiley & Sons
- Seitenzahl: 336
- Erscheinungstermin: 20. Juli 2012
- Englisch
- ISBN-13: 9781118310038
- Artikelnr.: 37345346
- Verlag: John Wiley & Sons
- Seitenzahl: 336
- Erscheinungstermin: 20. Juli 2012
- Englisch
- ISBN-13: 9781118310038
- Artikelnr.: 37345346
DEV RAHEJA is President of Raheja Consulting, Inc. For over thirty years, he has served clients in numerous industries, including aerospace, medical devices, auto, and consumer products. Raheja is also the coauthor of Assurance Technologies Principles and Practices, Second Edition (Wiley). LOUIS J. GULLO is Senior Principal Systems Engineer at Raytheon Missile Systems in Tucson, Arizona. A retired U.S. Army Lieutenant Colonel, Gullo has more than thirty years' experience in military, space, and commercial programs. He is a Senior Member of the IEEE and Chair of the IEEE Reliability Society Standards Committee.
Contributors xiii Foreword xv Preface xvii Introduction: What You Will
Learn xix 1 Design for Reliability Paradigms 1 Dev Raheja Why Design for
Reliability? 1 Reflections on the Current State of the Art 2 The Paradigms
for Design for Reliability 4 Summary 13 References 13 2 Reliability Design
Tools 15 Joseph A. Childs Introduction 15 Reliability Tools 19 Test Data
Analysis 31 Summary 34 References 35 3 Developing Reliable Software 37
Samuel Keene Introduction and Background 37 Software Reliability:
Definitions and Basic Concepts 40 Software Reliability Design
Considerations 44 Operational Reliability Requires Effective Change
Management 48 Execution-Time Software Reliability Models 48 Software
Reliability Prediction Tools Prior to Testing 49 References 51 4
Reliability Models 53 Louis J. Gullo Introduction 53 Reliability Block
Diagram: System Modeling 56 Example of System Reliability Models Using RBDs
57 Reliability Growth Model 60 Similarity Analysis and Categories of a
Physical Model 60 Monte Carlo Models 62 Markov Models 62 References 64 5
Design Failure Modes, Effects, and Criticality Analysis 67 Louis J. Gullo
Introduction to FMEA and FMECA 67 Design FMECA 68 Principles of FMECA-MA 71
Design FMECA Approaches 72 Example of a Design FMECA Process 74 Risk
Priority Number 82 Final Thoughts 86 References 86 6 Process Failure Modes,
Effects, and Criticality Analysis 87 Joseph A. Childs Introduction 87
Principles of P-FMECA 87 Use of P-FMECA 88 What Is Required Before Starting
90 Performing P-FMECA Step by Step 91 Improvement Actions 98 Reporting
Results 100 Suggestions for Additional Reading 101 7 FMECA Applied to
Software Development 103 Robert W. Stoddard Introduction 103 Scoping an
FMECA for Software Development 104 FMECA Steps for Software Development 106
Important Notes on Roles and Responsibilities with Software FMECA 116
Lessons Learned from Conducting Software FMECA 117 Conclusions 119
References 120 8 Six Sigma Approach to Requirements Development 121 Samuel
Keene Early Experiences with Design of Experiments 121 Six Sigma
Foundations 124 The Six Sigma Three-Pronged Initiative 126 The RASCI Tool
128 Design for Six Sigma 129 Requirements Development: The Principal
Challenge to System Reliability 130 The GQM Tool 131 The Mind Mapping Tool
132 References 135 9 Human Factors in Reliable Design 137 Jack Dixon Human
Factors Engineering 137 A Design Engineer's Interest in Human Factors 138
Human-Centered Design 138 Human Factors Analysis Process 144 Human Factors
and Risk 150 Human Error 150 Design for Error Tolerance 153 Checklists 154
Testing to Validate Human Factors in Design 154 References 154 10 Stress
Analysis During Design to Eliminate Failures 157 Louis J. Gullo Principles
of Stress Analysis 157 Mechanical Stress Analysis or Durability Analysis
158 Finite Element Analysis 158 Probabilistic vs. Deterministic Methods and
Failures 159 How Stress Analysis Aids Design for Reliability 159 Derating
and Stress Analysis 160 Stress vs. Strength Curves 161 Software Stress
Analysis and Testing 166 Structural Reinforcement to Improve Structural
Integrity 167 References 167 11 Highly Accelerated Life Testing 169 Louis
J. Gullo Introduction 169 Time Compression 173 Test Coverage 174
Environmental Stresses of HALT 175 Sensitivity to Stresses 176 Design
Margin 178 Sample Size 180 Conclusions 180 Reference 181 12 Design for
Extreme Environments 183 Steven S. Austin Overview 183 Designing for
Extreme Environments 183 Designing for Cold 184 Designing for Heat 186
References 191 13 Design for Trustworthiness 193 Lawrence Bernstein and C.
M. Yuhas Introduction 193 Modules and Components 196 Politics of Reuse 200
Design Principles 201 Design Constraints That Make Systems Trustworthy 204
Conclusions 210 References and Notes 211 14 Prognostics and Health
Management Capabilities to Improve Reliability 213 Louis J. Gullo
Introduction 213 PHM Is Department of Defense Policy 216 Condition-Based
Maintenance vs. Time-Based Maintenance 216 Monitoring and Reasoning of
Failure Precursors 217 Monitoring Environmental and Usage Loads for Damage
Modeling 218 Fault Detection, Fault Isolation, and Prognostics 218 Sensors
for Automatic Stress Monitoring 220 References 221 15 Reliability
Management 223 Joseph A. Childs Introduction 223 Planning, Execution, and
Documentation 229 Closing the Feedback Loop: Reliability Assessment,
Problem Solving, and Growth 232 References 233 16 Risk Management,
Exception Handling, and Change Management 235 Jack Dixon Introduction to
Risk 235 Importance of Risk Management 236 Why Many Risks Are Overlooked
237 Program Risk 239 Design Risk 241 Risk Assessment 242 Risk
Identification 243 Risk Estimation 244 Risk Evaluation 245 Risk Mitigation
247 Risk Communication 248 Risk and Competitiveness 249 Risk Management in
the Change Process 249 Configuration Management 249 References 251 17
Integrating Design for Reliability with Design for Safety 253 Brian
Moriarty Introduction 253 Start of Safety Design 254 Reliability in System
Safety Design 255 Safety Analysis Techniques 255 Establishing Safety
Assessment Using the Risk Assessment Code Matrix 260 Design and Development
Process for Detailed Safety Design 261 Verification of Design for Safety
Includes Reliability 261 Examples of Design for Safety with Reliability
Data 262 Final Thoughts 266 References 266 18 Organizational Reliability
Capability Assessment 267 Louis J. Gullo Introduction 267 The Benefits of
IEEE 1624-2008 269 Organizational Reliability Capability 270 Reliability
Capability Assessment 271 Design Capability and Performability 271 IEEE
1624 Scoring Guidelines 276 SEI CMMI Scoring Guidelines 277 Organizational
Reliability Capability Assessment Process 278 Advantages of High
Reliability 282 Conclusions 283 References 284 Index 285
Learn xix 1 Design for Reliability Paradigms 1 Dev Raheja Why Design for
Reliability? 1 Reflections on the Current State of the Art 2 The Paradigms
for Design for Reliability 4 Summary 13 References 13 2 Reliability Design
Tools 15 Joseph A. Childs Introduction 15 Reliability Tools 19 Test Data
Analysis 31 Summary 34 References 35 3 Developing Reliable Software 37
Samuel Keene Introduction and Background 37 Software Reliability:
Definitions and Basic Concepts 40 Software Reliability Design
Considerations 44 Operational Reliability Requires Effective Change
Management 48 Execution-Time Software Reliability Models 48 Software
Reliability Prediction Tools Prior to Testing 49 References 51 4
Reliability Models 53 Louis J. Gullo Introduction 53 Reliability Block
Diagram: System Modeling 56 Example of System Reliability Models Using RBDs
57 Reliability Growth Model 60 Similarity Analysis and Categories of a
Physical Model 60 Monte Carlo Models 62 Markov Models 62 References 64 5
Design Failure Modes, Effects, and Criticality Analysis 67 Louis J. Gullo
Introduction to FMEA and FMECA 67 Design FMECA 68 Principles of FMECA-MA 71
Design FMECA Approaches 72 Example of a Design FMECA Process 74 Risk
Priority Number 82 Final Thoughts 86 References 86 6 Process Failure Modes,
Effects, and Criticality Analysis 87 Joseph A. Childs Introduction 87
Principles of P-FMECA 87 Use of P-FMECA 88 What Is Required Before Starting
90 Performing P-FMECA Step by Step 91 Improvement Actions 98 Reporting
Results 100 Suggestions for Additional Reading 101 7 FMECA Applied to
Software Development 103 Robert W. Stoddard Introduction 103 Scoping an
FMECA for Software Development 104 FMECA Steps for Software Development 106
Important Notes on Roles and Responsibilities with Software FMECA 116
Lessons Learned from Conducting Software FMECA 117 Conclusions 119
References 120 8 Six Sigma Approach to Requirements Development 121 Samuel
Keene Early Experiences with Design of Experiments 121 Six Sigma
Foundations 124 The Six Sigma Three-Pronged Initiative 126 The RASCI Tool
128 Design for Six Sigma 129 Requirements Development: The Principal
Challenge to System Reliability 130 The GQM Tool 131 The Mind Mapping Tool
132 References 135 9 Human Factors in Reliable Design 137 Jack Dixon Human
Factors Engineering 137 A Design Engineer's Interest in Human Factors 138
Human-Centered Design 138 Human Factors Analysis Process 144 Human Factors
and Risk 150 Human Error 150 Design for Error Tolerance 153 Checklists 154
Testing to Validate Human Factors in Design 154 References 154 10 Stress
Analysis During Design to Eliminate Failures 157 Louis J. Gullo Principles
of Stress Analysis 157 Mechanical Stress Analysis or Durability Analysis
158 Finite Element Analysis 158 Probabilistic vs. Deterministic Methods and
Failures 159 How Stress Analysis Aids Design for Reliability 159 Derating
and Stress Analysis 160 Stress vs. Strength Curves 161 Software Stress
Analysis and Testing 166 Structural Reinforcement to Improve Structural
Integrity 167 References 167 11 Highly Accelerated Life Testing 169 Louis
J. Gullo Introduction 169 Time Compression 173 Test Coverage 174
Environmental Stresses of HALT 175 Sensitivity to Stresses 176 Design
Margin 178 Sample Size 180 Conclusions 180 Reference 181 12 Design for
Extreme Environments 183 Steven S. Austin Overview 183 Designing for
Extreme Environments 183 Designing for Cold 184 Designing for Heat 186
References 191 13 Design for Trustworthiness 193 Lawrence Bernstein and C.
M. Yuhas Introduction 193 Modules and Components 196 Politics of Reuse 200
Design Principles 201 Design Constraints That Make Systems Trustworthy 204
Conclusions 210 References and Notes 211 14 Prognostics and Health
Management Capabilities to Improve Reliability 213 Louis J. Gullo
Introduction 213 PHM Is Department of Defense Policy 216 Condition-Based
Maintenance vs. Time-Based Maintenance 216 Monitoring and Reasoning of
Failure Precursors 217 Monitoring Environmental and Usage Loads for Damage
Modeling 218 Fault Detection, Fault Isolation, and Prognostics 218 Sensors
for Automatic Stress Monitoring 220 References 221 15 Reliability
Management 223 Joseph A. Childs Introduction 223 Planning, Execution, and
Documentation 229 Closing the Feedback Loop: Reliability Assessment,
Problem Solving, and Growth 232 References 233 16 Risk Management,
Exception Handling, and Change Management 235 Jack Dixon Introduction to
Risk 235 Importance of Risk Management 236 Why Many Risks Are Overlooked
237 Program Risk 239 Design Risk 241 Risk Assessment 242 Risk
Identification 243 Risk Estimation 244 Risk Evaluation 245 Risk Mitigation
247 Risk Communication 248 Risk and Competitiveness 249 Risk Management in
the Change Process 249 Configuration Management 249 References 251 17
Integrating Design for Reliability with Design for Safety 253 Brian
Moriarty Introduction 253 Start of Safety Design 254 Reliability in System
Safety Design 255 Safety Analysis Techniques 255 Establishing Safety
Assessment Using the Risk Assessment Code Matrix 260 Design and Development
Process for Detailed Safety Design 261 Verification of Design for Safety
Includes Reliability 261 Examples of Design for Safety with Reliability
Data 262 Final Thoughts 266 References 266 18 Organizational Reliability
Capability Assessment 267 Louis J. Gullo Introduction 267 The Benefits of
IEEE 1624-2008 269 Organizational Reliability Capability 270 Reliability
Capability Assessment 271 Design Capability and Performability 271 IEEE
1624 Scoring Guidelines 276 SEI CMMI Scoring Guidelines 277 Organizational
Reliability Capability Assessment Process 278 Advantages of High
Reliability 282 Conclusions 283 References 284 Index 285
Contributors xiii Foreword xv Preface xvii Introduction: What You Will
Learn xix 1 Design for Reliability Paradigms 1 Dev Raheja Why Design for
Reliability? 1 Reflections on the Current State of the Art 2 The Paradigms
for Design for Reliability 4 Summary 13 References 13 2 Reliability Design
Tools 15 Joseph A. Childs Introduction 15 Reliability Tools 19 Test Data
Analysis 31 Summary 34 References 35 3 Developing Reliable Software 37
Samuel Keene Introduction and Background 37 Software Reliability:
Definitions and Basic Concepts 40 Software Reliability Design
Considerations 44 Operational Reliability Requires Effective Change
Management 48 Execution-Time Software Reliability Models 48 Software
Reliability Prediction Tools Prior to Testing 49 References 51 4
Reliability Models 53 Louis J. Gullo Introduction 53 Reliability Block
Diagram: System Modeling 56 Example of System Reliability Models Using RBDs
57 Reliability Growth Model 60 Similarity Analysis and Categories of a
Physical Model 60 Monte Carlo Models 62 Markov Models 62 References 64 5
Design Failure Modes, Effects, and Criticality Analysis 67 Louis J. Gullo
Introduction to FMEA and FMECA 67 Design FMECA 68 Principles of FMECA-MA 71
Design FMECA Approaches 72 Example of a Design FMECA Process 74 Risk
Priority Number 82 Final Thoughts 86 References 86 6 Process Failure Modes,
Effects, and Criticality Analysis 87 Joseph A. Childs Introduction 87
Principles of P-FMECA 87 Use of P-FMECA 88 What Is Required Before Starting
90 Performing P-FMECA Step by Step 91 Improvement Actions 98 Reporting
Results 100 Suggestions for Additional Reading 101 7 FMECA Applied to
Software Development 103 Robert W. Stoddard Introduction 103 Scoping an
FMECA for Software Development 104 FMECA Steps for Software Development 106
Important Notes on Roles and Responsibilities with Software FMECA 116
Lessons Learned from Conducting Software FMECA 117 Conclusions 119
References 120 8 Six Sigma Approach to Requirements Development 121 Samuel
Keene Early Experiences with Design of Experiments 121 Six Sigma
Foundations 124 The Six Sigma Three-Pronged Initiative 126 The RASCI Tool
128 Design for Six Sigma 129 Requirements Development: The Principal
Challenge to System Reliability 130 The GQM Tool 131 The Mind Mapping Tool
132 References 135 9 Human Factors in Reliable Design 137 Jack Dixon Human
Factors Engineering 137 A Design Engineer's Interest in Human Factors 138
Human-Centered Design 138 Human Factors Analysis Process 144 Human Factors
and Risk 150 Human Error 150 Design for Error Tolerance 153 Checklists 154
Testing to Validate Human Factors in Design 154 References 154 10 Stress
Analysis During Design to Eliminate Failures 157 Louis J. Gullo Principles
of Stress Analysis 157 Mechanical Stress Analysis or Durability Analysis
158 Finite Element Analysis 158 Probabilistic vs. Deterministic Methods and
Failures 159 How Stress Analysis Aids Design for Reliability 159 Derating
and Stress Analysis 160 Stress vs. Strength Curves 161 Software Stress
Analysis and Testing 166 Structural Reinforcement to Improve Structural
Integrity 167 References 167 11 Highly Accelerated Life Testing 169 Louis
J. Gullo Introduction 169 Time Compression 173 Test Coverage 174
Environmental Stresses of HALT 175 Sensitivity to Stresses 176 Design
Margin 178 Sample Size 180 Conclusions 180 Reference 181 12 Design for
Extreme Environments 183 Steven S. Austin Overview 183 Designing for
Extreme Environments 183 Designing for Cold 184 Designing for Heat 186
References 191 13 Design for Trustworthiness 193 Lawrence Bernstein and C.
M. Yuhas Introduction 193 Modules and Components 196 Politics of Reuse 200
Design Principles 201 Design Constraints That Make Systems Trustworthy 204
Conclusions 210 References and Notes 211 14 Prognostics and Health
Management Capabilities to Improve Reliability 213 Louis J. Gullo
Introduction 213 PHM Is Department of Defense Policy 216 Condition-Based
Maintenance vs. Time-Based Maintenance 216 Monitoring and Reasoning of
Failure Precursors 217 Monitoring Environmental and Usage Loads for Damage
Modeling 218 Fault Detection, Fault Isolation, and Prognostics 218 Sensors
for Automatic Stress Monitoring 220 References 221 15 Reliability
Management 223 Joseph A. Childs Introduction 223 Planning, Execution, and
Documentation 229 Closing the Feedback Loop: Reliability Assessment,
Problem Solving, and Growth 232 References 233 16 Risk Management,
Exception Handling, and Change Management 235 Jack Dixon Introduction to
Risk 235 Importance of Risk Management 236 Why Many Risks Are Overlooked
237 Program Risk 239 Design Risk 241 Risk Assessment 242 Risk
Identification 243 Risk Estimation 244 Risk Evaluation 245 Risk Mitigation
247 Risk Communication 248 Risk and Competitiveness 249 Risk Management in
the Change Process 249 Configuration Management 249 References 251 17
Integrating Design for Reliability with Design for Safety 253 Brian
Moriarty Introduction 253 Start of Safety Design 254 Reliability in System
Safety Design 255 Safety Analysis Techniques 255 Establishing Safety
Assessment Using the Risk Assessment Code Matrix 260 Design and Development
Process for Detailed Safety Design 261 Verification of Design for Safety
Includes Reliability 261 Examples of Design for Safety with Reliability
Data 262 Final Thoughts 266 References 266 18 Organizational Reliability
Capability Assessment 267 Louis J. Gullo Introduction 267 The Benefits of
IEEE 1624-2008 269 Organizational Reliability Capability 270 Reliability
Capability Assessment 271 Design Capability and Performability 271 IEEE
1624 Scoring Guidelines 276 SEI CMMI Scoring Guidelines 277 Organizational
Reliability Capability Assessment Process 278 Advantages of High
Reliability 282 Conclusions 283 References 284 Index 285
Learn xix 1 Design for Reliability Paradigms 1 Dev Raheja Why Design for
Reliability? 1 Reflections on the Current State of the Art 2 The Paradigms
for Design for Reliability 4 Summary 13 References 13 2 Reliability Design
Tools 15 Joseph A. Childs Introduction 15 Reliability Tools 19 Test Data
Analysis 31 Summary 34 References 35 3 Developing Reliable Software 37
Samuel Keene Introduction and Background 37 Software Reliability:
Definitions and Basic Concepts 40 Software Reliability Design
Considerations 44 Operational Reliability Requires Effective Change
Management 48 Execution-Time Software Reliability Models 48 Software
Reliability Prediction Tools Prior to Testing 49 References 51 4
Reliability Models 53 Louis J. Gullo Introduction 53 Reliability Block
Diagram: System Modeling 56 Example of System Reliability Models Using RBDs
57 Reliability Growth Model 60 Similarity Analysis and Categories of a
Physical Model 60 Monte Carlo Models 62 Markov Models 62 References 64 5
Design Failure Modes, Effects, and Criticality Analysis 67 Louis J. Gullo
Introduction to FMEA and FMECA 67 Design FMECA 68 Principles of FMECA-MA 71
Design FMECA Approaches 72 Example of a Design FMECA Process 74 Risk
Priority Number 82 Final Thoughts 86 References 86 6 Process Failure Modes,
Effects, and Criticality Analysis 87 Joseph A. Childs Introduction 87
Principles of P-FMECA 87 Use of P-FMECA 88 What Is Required Before Starting
90 Performing P-FMECA Step by Step 91 Improvement Actions 98 Reporting
Results 100 Suggestions for Additional Reading 101 7 FMECA Applied to
Software Development 103 Robert W. Stoddard Introduction 103 Scoping an
FMECA for Software Development 104 FMECA Steps for Software Development 106
Important Notes on Roles and Responsibilities with Software FMECA 116
Lessons Learned from Conducting Software FMECA 117 Conclusions 119
References 120 8 Six Sigma Approach to Requirements Development 121 Samuel
Keene Early Experiences with Design of Experiments 121 Six Sigma
Foundations 124 The Six Sigma Three-Pronged Initiative 126 The RASCI Tool
128 Design for Six Sigma 129 Requirements Development: The Principal
Challenge to System Reliability 130 The GQM Tool 131 The Mind Mapping Tool
132 References 135 9 Human Factors in Reliable Design 137 Jack Dixon Human
Factors Engineering 137 A Design Engineer's Interest in Human Factors 138
Human-Centered Design 138 Human Factors Analysis Process 144 Human Factors
and Risk 150 Human Error 150 Design for Error Tolerance 153 Checklists 154
Testing to Validate Human Factors in Design 154 References 154 10 Stress
Analysis During Design to Eliminate Failures 157 Louis J. Gullo Principles
of Stress Analysis 157 Mechanical Stress Analysis or Durability Analysis
158 Finite Element Analysis 158 Probabilistic vs. Deterministic Methods and
Failures 159 How Stress Analysis Aids Design for Reliability 159 Derating
and Stress Analysis 160 Stress vs. Strength Curves 161 Software Stress
Analysis and Testing 166 Structural Reinforcement to Improve Structural
Integrity 167 References 167 11 Highly Accelerated Life Testing 169 Louis
J. Gullo Introduction 169 Time Compression 173 Test Coverage 174
Environmental Stresses of HALT 175 Sensitivity to Stresses 176 Design
Margin 178 Sample Size 180 Conclusions 180 Reference 181 12 Design for
Extreme Environments 183 Steven S. Austin Overview 183 Designing for
Extreme Environments 183 Designing for Cold 184 Designing for Heat 186
References 191 13 Design for Trustworthiness 193 Lawrence Bernstein and C.
M. Yuhas Introduction 193 Modules and Components 196 Politics of Reuse 200
Design Principles 201 Design Constraints That Make Systems Trustworthy 204
Conclusions 210 References and Notes 211 14 Prognostics and Health
Management Capabilities to Improve Reliability 213 Louis J. Gullo
Introduction 213 PHM Is Department of Defense Policy 216 Condition-Based
Maintenance vs. Time-Based Maintenance 216 Monitoring and Reasoning of
Failure Precursors 217 Monitoring Environmental and Usage Loads for Damage
Modeling 218 Fault Detection, Fault Isolation, and Prognostics 218 Sensors
for Automatic Stress Monitoring 220 References 221 15 Reliability
Management 223 Joseph A. Childs Introduction 223 Planning, Execution, and
Documentation 229 Closing the Feedback Loop: Reliability Assessment,
Problem Solving, and Growth 232 References 233 16 Risk Management,
Exception Handling, and Change Management 235 Jack Dixon Introduction to
Risk 235 Importance of Risk Management 236 Why Many Risks Are Overlooked
237 Program Risk 239 Design Risk 241 Risk Assessment 242 Risk
Identification 243 Risk Estimation 244 Risk Evaluation 245 Risk Mitigation
247 Risk Communication 248 Risk and Competitiveness 249 Risk Management in
the Change Process 249 Configuration Management 249 References 251 17
Integrating Design for Reliability with Design for Safety 253 Brian
Moriarty Introduction 253 Start of Safety Design 254 Reliability in System
Safety Design 255 Safety Analysis Techniques 255 Establishing Safety
Assessment Using the Risk Assessment Code Matrix 260 Design and Development
Process for Detailed Safety Design 261 Verification of Design for Safety
Includes Reliability 261 Examples of Design for Safety with Reliability
Data 262 Final Thoughts 266 References 266 18 Organizational Reliability
Capability Assessment 267 Louis J. Gullo Introduction 267 The Benefits of
IEEE 1624-2008 269 Organizational Reliability Capability 270 Reliability
Capability Assessment 271 Design Capability and Performability 271 IEEE
1624 Scoring Guidelines 276 SEI CMMI Scoring Guidelines 277 Organizational
Reliability Capability Assessment Process 278 Advantages of High
Reliability 282 Conclusions 283 References 284 Index 285