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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:
Acceso en línea:Texto completo

MARC

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520 |a 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 safe conditions and minimum risk of accidents. The book covers safety design practices, which will result in improved safety, fewer accidents, and substantial savings in life cycle costs for producers and users. Readers who apply DfSa principles can expect to have a dramatic improvement in the ability to compete in global markets. They will also find a wealth of design practices not covered in typical engineering books-allowing them to think outside the box when developing safety requirements. Design Safety is already a high demand field due to its importance to system design and will be even more vital for engineers in multiple design disciplines as more systems become increasingly complex and liabilities increase. Therefore, risk mitigation methods to design systems with safety features are becoming more important. Designing systems for safety has been a high priority for many safety-critical systems-especially in the aerospace and military industries. However, with the expansion of technological innovations into other market places, industries that had not previously considered safety design requirements are now using the technology in applications. Design for Safety: -Covers trending topics and the latest technologies -Provides ten paradigms for managing and designing systems for safety and uses them as guiding themes throughout the book -Logically defines the parameters and concepts, sets the safety program and requirements, covers basic methodologies, investigates lessons from history, and addresses specialty topics within the topic of Design for Safety (DfSa) -Supplements other books in the series on Quality and Reliability Engineering Design for Safety is an ideal book for new and experienced engineers and managers who are involved with design, testing, and maintenance of safety critical applications. It is also helpful for advanced undergraduate and postgraduate students in engineering. Design for Safety is the second in a series of "Design for" books. Design for Reliability was the first in the series with more planned for the future. 
505 0 |a 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. 
505 8 |a 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. 
505 8 |a 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. 
505 8 |a 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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