This book demonstrates how quantitative resilience methodologies can be applied to a wide range of space systems as an extension of conventional systems engineering processes. It addresses the full spectrum of threats facing modern space systems and provides a comprehensive framework for ensuring mission continuity.
Resilient Space Systems Design: An Introduction demonstrates how quantitative resilience methodologies can be applied to a wide range of space systems as an extension of conventional systems engineering processes. This holistic approach includes establishing core definitions, requirements definition, mathematical modelling, and cost and performance trades. It addresses the full spectrum of threats facing modern space systems, from natural hazards to hostile actions, and provides a comprehensive framework for ensuring mission continuity.
The new edition includes expanded discussions of the systems engineering process, the relevance of qualitative resilience properties, and the use of algorithms and artificial intelligence to increase resilience. It examines the effects of various threats on space systems and ground elements, with particular attention to emerging challenges posed by proliferated low Earth orbit constellations implementing mesh networks. The book also features extended coverage of calculation of avoidance, recovery, reconstitution, and a single resilience value over multiple capabilities, threats, and mitigations.
This book is intended for aerospace engineers, space systems engineers and architects, communications engineers, and network engineers working on improving the survivability and operational continuity of commercial, civil, and military space assets.
1. The Space System.
2. Defining and Evaluating Resilience.
3. Threats.
4. Threat Mitigation.
5. Systems Engineering and Resilience.
6. Modeling and
Calculating Resilience.
7. Designing for Resilience.
8. Applying Resilient
Design Techniques.
9. The Future of Resilient Space System Design.
10.
References.
Ron Burch is the former director of Advanced Military Satellite Communications (MILSATCOM) for the Boeing Companys Space and Launch division. His career spanned over 35 years of satellite systems design and development experience at the Boeing Company and Hughes Aircraft Company. He continues to be active as an independent technical consultant to both the U.S. Government and industry. In addition, Mr. Burch continues to teach a Resilient Space Systems Design class at Loyola Marymount University in Los Angles, California. He is an acknowledged subject matter expert in the emerging discipline of space systems resilience and has spoken both domestically and internationally on the subject. His roles have included RF, optical, and digital subsystem and payload design, systems engineering, space technology development, and leadership positions including program management. Mr. Burch received a bachelors degree in electrical engineering (BSEE) from California State University, Fresno, and a masters degree (MSEE) from the California Institute of Technology (Caltech) with an emphasis in communications science. He has published numerous technical papers and is named on two U.S. patents.
