Time-Critical Cooperative Control of Autonomous Air Vehicles
Autor Isaac Kaminer, António M. Pascoal, Enric Xargay, Naira Hovakimyan, Venanzio Cichella, Vladimir Dobrokhodoven Limba Engleză Paperback – 3 aug 2017
By including case studies of fixed-wing and multirotor UAVs, the book effectively broadens the scope of application of the methodologies developed. This theoretical presentation is complemented with the results of flight tests with real UAVs, and is an ideal reference for researchers and practitioners from academia, research labs, commercial companies, government workers, and those in the international aerospace industry.
- Addresses important topics related to time-critical cooperative control of UAVs
- Describes solutions to the problems rooted in solid dynamical systems theory
- Applies the solutions developed to fixed-wing and multirotor UAVs
- Includes the results of field tests with both classes of UAVs
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Specificații
ISBN-13: 9780128099469
ISBN-10: 0128099461
Pagini: 270
Dimensiuni: 152 x 229 x 23 mm
Editura: ELSEVIER SCIENCE
ISBN-10: 0128099461
Pagini: 270
Dimensiuni: 152 x 229 x 23 mm
Editura: ELSEVIER SCIENCE
Public țintă
Research engineers and practicing engineers working with controls, especially cooperative control of multi-agent systems and unmanned aerial vehicles.Cuprins
Part One Time-Critical Cooperative Control: An Overview1. Introduction2. General Framework for Vehicle Cooperation
Part Two Cooperative Control of Fixed-Wing Air Vehicles3. 3D Path-Following Control of Fixed-Wing Air Vehicles4. Time Coordination of Fixed-Wing Air Vehicles5. Meeting Absolute Temporal Specifications6. Time Coordination Under Quantization7. Time Coordination Under Low Connectivity8. Flight Tests: Cooperative Road Search
Part Three Cooperative Control of Multirotor Air Vehicles9. 3D Path-Following Control of Multirotor Air Vehicles10. Time Coordination of Multirotor Air Vehicles11. Flight Tests of Multirotor UAVs
Part Four Final Considerations12. Summary and Concluding Remarks
AppendixA. Mathematical BackgroundB. Proofs and Derivations
Part Two Cooperative Control of Fixed-Wing Air Vehicles3. 3D Path-Following Control of Fixed-Wing Air Vehicles4. Time Coordination of Fixed-Wing Air Vehicles5. Meeting Absolute Temporal Specifications6. Time Coordination Under Quantization7. Time Coordination Under Low Connectivity8. Flight Tests: Cooperative Road Search
Part Three Cooperative Control of Multirotor Air Vehicles9. 3D Path-Following Control of Multirotor Air Vehicles10. Time Coordination of Multirotor Air Vehicles11. Flight Tests of Multirotor UAVs
Part Four Final Considerations12. Summary and Concluding Remarks
AppendixA. Mathematical BackgroundB. Proofs and Derivations