Design for Safety.

A one-stop reference guide to design for safety principles and applications Design for Safety (DfSa) provides design engineers and engineering managers with a range of tools and techniques for incorporating safety into the design process for complex systems. It explains how to design for maximum saf...

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Detalles Bibliográficos
Clasificación:Libro Electrónico
Autor principal: Gullo, Louis J.
Otros Autores: Dixon, Jack
Formato: Electrónico eBook
Idioma:Inglés
Publicado: Newark : John Wiley & Sons, Incorporated, 2017.
Colección:Quality and Reliability Engineering Ser.
Temas:
System safety.
Sécurité des systèmes.
TECHNOLOGY & ENGINEERING > Engineering (General)
System safety
Acceso en línea:Texto completo
Tabla de Contenidos:
  • Intro
  • Title Page
  • Table of Contents
  • Preface
  • Reference
  • Acknowledgments
  • Introduction: What You Will Learn
  • 1 Design for Safety Paradigms
  • 1.1 Why Design for System Safety?
  • 1.2 Reflections on the Current State of the Art
  • 1.3 Paradigms for Design for Safety
  • 1.4 Create Your Own Paradigms
  • 1.5 Summary
  • References
  • 2 The History of System Safety
  • 2.1 Introduction
  • 2.2 Origins of System Safety
  • 2.3 Tools of the Trade
  • 2.4 Benefits of System Safety
  • 2.5 System Safety Management
  • 2.6 Integrating System Safety into the Business Process
  • References
  • Suggestions for Additional Reading
  • 3 System Safety Program Planning and Management
  • 3.1 Management of the System Safety Program
  • 3.2 Engineering Viewpoint
  • 3.3 Safety Integrated in Systems Engineering
  • 3.4 Key Interfaces
  • 3.5 Planning, Execution, and Documentation
  • 3.6 System Safety Tasks
  • References
  • Suggestions for Additional Reading
  • 4 Managing Risks and Product Liabilities
  • 4.1 Introduction
  • 4.2 Risk
  • 4.3 Risk Management
  • 4.4 What Happens When the Paradigms for Design for Safety Are Not Followed?
  • 4.5 Tort Liability
  • 4.6 An Introduction to Product Liability Law
  • 4.7 Famous Legal Court Cases Involving Product Liability Law
  • 4.8 Negligence
  • 4.9 Warnings
  • 4.10 The Rush to Market and the Risk of Unknown Hazards
  • 4.11 Warranty
  • 4.12 The Government Contractor Defense
  • 4.13 Legal Conclusions Involving Defective and Unsafe Products
  • References
  • Suggestions for Additional Reading
  • 5 Developing System Safety Requirements
  • 5.1 Why Do We Need Safety Requirements?
  • 5.2 Design for Safety Paradigm 3 Revisited
  • 5.3 How Do We Drive System Safety Requirements?
  • 5.4 What Is a System Requirement?
  • 5.5 Hazard Control Requirements
  • 5.6 Developing Good Requirements.
  • 5.7 Example of Certification and Validation Requirements for a PSDI
  • 5.8 Examples of Requirements from STANAG 4404
  • 5.9 Summary
  • References
  • 6 System Safety Design Checklists
  • 6.1 Background
  • 6.2 Types of Checklists
  • 6.3 Use of Checklists
  • References
  • Suggestions for Additional Reading
  • Additional Sources of Checklists
  • 7 System Safety Hazard Analysis
  • 7.1 Introduction to Hazard Analyses
  • 7.2 Risk
  • 7.3 Design Risk
  • 7.4 Design Risk Management Methods and Hazard Analyses
  • 7.5 Hazard Analysis Tools
  • 7.6 Hazard Tracking
  • 7.7 Summary
  • References
  • Suggestions for Additional Reading
  • 8 Failure Modes, Effects, and Criticality Analysis for System Safety
  • 8.1 Introduction
  • 8.2 The Design FMECA (D-FMECA)
  • 8.3 How Are Single Point Failures Eliminated or Avoided in the Design?
  • 8.4 Software Design FMECA
  • 8.5 What Is a PFMECA?
  • 8.6 Conclusion
  • Acknowledgments
  • References
  • Suggestions for Additional Reading
  • 9 Fault Tree Analysis for System Safety
  • 9.1 Background
  • 9.2 What Is a Fault Tree?
  • 9.3 Methodology
  • 9.4 Cut Sets
  • 9.5 Quantitative Analysis of Fault Trees
  • 9.6 Automated Fault Tree Analysis
  • 9.7 Advantages and Disadvantages
  • 9.8 Example
  • 9.9 Conclusion
  • References
  • Suggestions for Additional Reading
  • 10 Complementary Design Analysis Techniques
  • 10.1 Background
  • 10.2 Discussion of Less Used Techniques
  • 10.3 Other Analysis Techniques
  • References
  • Suggestions for Additional Reading
  • 11 Process Safety Management and Analysis
  • 11.1 Background
  • 11.2 Elements of Process Safety Management
  • 11.3 Process Hazard Analyses
  • 11.4 Other Related Regulations
  • 11.5 Inherently Safer Design
  • 11.6 Summary
  • References
  • Suggestions for Additional Reading
  • 12 System Safety Testing
  • 12.1 Purpose of System Safety Testing
  • 12.2 Test Strategy and Test Architecture.
  • 12.3 Develop System Safety Test Plans
  • 12.4 Regulatory Compliance Testing
  • 12.5 The Value of PHM for System Safety Testing
  • 12.6 Leveraging Reliability Test Approaches for Safety Testing
  • 12.7 Safety Test Data Collection
  • 12.8 Test Results and What to Do with the Results
  • 12.9 Design for Testability
  • 12.10 Test Modeling
  • 12.11 Summary
  • References
  • 13 Integrating Safety with Other Functional Disciplines
  • 13.1 Introduction
  • 13.2 Raytheon's Code of Conduct
  • 13.3 Effective Use of the Paradigms for Design for Safety
  • 13.4 How to Influence People
  • 13.5 Practice Emotional Intelligence
  • 13.6 Practice Positive Deviance to Influence People
  • 13.7 Practice "Pay It Forward"
  • 13.8 Interfaces with Customers
  • 13.9 Interfaces with Suppliers
  • 13.10 Five Hats for Multi-Disciplined Engineers (A Path Forward)
  • 13.11 Conclusions
  • References
  • 14 Design for Reliability Integrated with System Safety
  • 14.1 Introduction
  • 14.2 What Is Reliability?
  • 14.3 System Safety Design with Reliability Data
  • 14.4 How Is Reliability Data Translated to Probability of Occurrence?
  • 14.5 Verification of Design for Safety Including Reliability Results
  • 14.6 Examples of Design for Safety with Reliability Data
  • 14.7 Conclusions
  • Acknowledgment
  • References
  • 15 Design for Human Factors Integrated with System Safety
  • 15.1 Introduction
  • 15.2 Human Factors Engineering
  • 15.3 Human-Centered Design
  • 15.4 Role of Human Factors in Design
  • 15.5 Human Factors Analysis Process
  • 15.6 Human Factors and Risk
  • 15.7 Checklists
  • 15.8 Testing to Validate Human Factors in Design
  • Acknowledgment
  • References
  • Suggestions for Additional Reading
  • 16 Software Safety and Security
  • 16.1 Introduction
  • 16.2 Definitions of Cybersecurity and Software Assurance
  • 16.3 Software Safety and Cybersecurity Development Tasks.
  • 16.4 Software FMECA
  • 16.5 Examples of Requirements for Software Safety
  • 16.6 Example of Numerical Accuracy Where 2 + 2 = 5
  • 16.7 Conclusions
  • Acknowledgments
  • References
  • 17 Lessons Learned
  • 17.1 Introduction
  • 17.2 Capturing Lessons Learned Is Important
  • 17.3 Analyzing Failure
  • 17.4 Learn from Success and from Failure
  • 17.5 Near Misses
  • 17.6 Continuous Improvement
  • 17.7 Lessons Learned Process
  • 17.8 Lessons Learned Examples
  • 17.9 Summary
  • References
  • Suggestions for Additional Reading
  • 18 Special Topics on System Safety
  • 18.1 Introduction
  • 18.2 Airworthiness and Flight Safety
  • 18.3 Statistical Data Comparison Between Commercial Air Travel and Motor Vehicle Travel
  • 18.4 Safer Ground Transportation Through Autonomous Vehicles
  • 18.5 The Future of Commercial Space Travel
  • 18.6 Summary
  • References
  • Appendix A: Hazards Checklist
  • Reference
  • Appendix B: System Safety Design Verification Checklist
  • Reference
  • Index
  • End User License Agreement.

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