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Cooperative Control of Spacecraft Formation Flying: From Anti-Communication Delays to Resources Saving provides an in-depth, practically focused, exploration of secure cooperative control for spacecraft formation flying that addresses real-world challenges including communication latency, resource constraints, and information security, balancing foundational theory with actionable solutions, tailored to complex, resource-limited environments A comprehensive reference source for aerospace engineers and researchers covering anti-communication delays and resource-saving coordination strategies in spacecraft formation flying. For professionals and researchers in space systems, robotics and control engineering, the book provides detailed descriptions of robust security measures and practical application insights. The integration of secure communication protocols with control methods makes the book particularly relevant for professionals in high-stakes environments, where cyber threats and resource limitations are critical. For space agency mission planners and aerospace cybersecurity experts, the project addresses critical issues in secure, delay-tolerant communication and resource optimization for coordinated spacecraft missions. This enhances the development of secure and resilient communication protocols, which are critical to prevent data breaches and ensure reliable inter-spacecraft coordination in adversarial environments. The integration of advanced algorithms and the emphasis on real-world challenges, particularly the communication security issue, provides readers with a unique perspective that is missing in existing literature. The book equips readers with detailed information on advanced control strategies for multi-spacecraft coordination, particularly methods that address communication delays and optimize resource use
List of contents
1. Introduction and Literature Review
2. Preliminaries and Mathematical Model
3. Delay-Dependent Attitude Coordinated Control with Constant Delays
4. Integral SMC-Based Anti-Communication Delays Attitude Coordination
5. Adaptive Attitude Coordinated with Time-Varying Communication Delays
6. Robust Attitude Coordinated Control with Delays and Input Saturation
7. Event-Based Coordinated Control with Communication Resources Constraints
8. Event-Driven Coordinated Control with Limited Communication and Computation Capacities
9. A Unified Event-Triggered Observer-based Distributed Control
10. Distance-Dependent Event-Driven Connectivity-Preserving Coordinated Control.
11. Adaptive Neural Coordinated Control with Periodic Triggering Sampling
12. Secure Distributed Control for Multi-Spacecraft against Eavesdropping Attacks
13. Conclusion
About the author
Dr. Shi received her Ph.D. degree in navigation, guidance, and control with Beihang University, Beijing, China She is currently a research fellow at the School of Mechanical and Aerospace Engineering, Nanyang Technological University. Her current research interests include spacecraft formation flying, multi-agent systems, distributed control, event-triggered control, and adaptive dynamic programming and encrypted control
