The creation of complex integrated systems is, in itself, complex. It requires immense planning, a large team of people with diverse backgrounds, based in dispersed geographical locations (and countries) supposedly working to a coordinated schedule and cost.
The creation of complex integrated systems is, in itself, complex. It requires immense planning and a large team of people with diverse backgrounds based in dispersed geographical locations (and countries) supposedly working to a coordinated schedule and cost. The systems engineering task is not new, but recent scales most definitely are. The world is now capable of designing and manufacturing systems whose complexity was not considered possible 10 years ago. While many are trained to think in terms of a complete system, where ‘everything’ is designed and produced by a single project team, today such systems involve integrating subsystems and components (which are also complex) that have been developed by other project teams. Inevitably, this introduces additional complexities, involving elements out of the direct control of the project, but which are essential to its overall success.
In addition to traditional systems engineering topics of hardware and software design, testability, and manufacturability, there are wider issues to be contemplated: project planning; communication language (an issue for international teams); units of measure (imperial vs. metric) used across members of the team; supply chains (pandemics, military action, and natural disasters); legal issues based on place of production and sale; the ethics associated with target use; and the threat of cyberattack. This book is the first attempt to bring many of these issues together to highlight the complexities that need to be considered in modern system design. It is neither exhaustive nor comprehensive, but it gives pointers to the topics for the reader to follow up on in more detail.
1. An Overview of Complex System Design. PART 1 System Planning
2.
Requirements Types Design and Test.
3. Project Planning.
4. System
Decomposition.
5. Systems Engineering Vee.
6. Economics of Design and Test.
7. Cyber-Physical Systems.
8. Logistics and Supply Chain Management. PART 2
System Design
9. Chip Level Design and Test.
10. Board-Level Design and Test.
11. Power Distribution.
12. Design Patterns and Reusability.
13. Test-Driven
Development. PART 3 System Analysis
14. Reliability.
15. Availability.
16.
Maintainability.
17. Performance Evaluation.
18. Optimizing Complex Systems
Operation. PART 4 System Testing
19. Types of Testing.
20. Software Text.
21.
Error Handling.
22. Automated Test Systems Design.
23. Interoperability. PART
5 System Health 24.Uncertainty and Uncertainty Propagation.
25. Fault
Detection, Localization, and Isolation.
26. Risk and Risk Analysis.
27.
Risk-Based Prognostics and Health Management.
28. Structural Health
Monitoring. PART 6 System Security
29. Risk Management Framework.
30.
Information Assurance, Vulnerability Analysis, and Remediation.
31.
Cryptographic Systems.
32. Software Security. PART 7 System Usage
33. Human
Systems Interaction - Interface Design.
34. Human and Privacy Rights.
35.
Humanitarian Well-Being.
36. The Social Impacts of Complex Systems.
Anthony P. Ambler is a fellow of the IEEE, elected For contributions to economics of testing complex digital devices and systems. His research interests are in test economics, system test, and diagnosis. He received his B.Sc., M.Sc., and Ph.D. from the University of Manchester Institute of Science and Technology. He was appointed to a chair in Test Technology at Brunel University (UK) and then moved to the USA. He became chairman of Electrical & Computer Engineering at the University of Texas at Austin, then dean of Engineering & Computing at the University of South Carolina, and recently as dean of Technology at the University of Houston. In addition to his research work, he created the MS degree program in Engineering Management at UT Austin. He has acted as chair of the Organizing Committee of the European Design and Test Conference, general chair and program chair of IEEE International Test Conference and of IEEE International Conference on Computer Design. He has created a number of Workshops including on Test Economics, System Test and Diagnosis, and Production Test Automation.
John W. Sheppard is a Norm Asbjornson College of Engineering Distinguished Professor in the Gianforte School of Computing at Montana State University. His research interests include fault diagnosis/prognosis of complex systems, modelbased and Bayesian reasoning, explainable and ethical artificial intelligence, and distributed populationbased algorithms. He is a fellow of the IEEE, elected 'For contributions to systemlevel diagnosis and prognosis'. He received his BS in computer science from Southern Methodist University and his MS and PhD in computer science from Johns Hopkins University. Before entering academia fulltime, he was a member of the industry for 20 years where his prior position was as a research fellow at ARINC Incorporated. He has been a longtime leader in the IEEE Standards Association, chairing several working groups focused on publishing standards related to complex system test and diagnosis. Previously, he also served as the designated representative from the IEEE Computer Society to the IEEE Standards Coordinating Committee 20 on Test and Diagnosis for Electronic Systems.
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