Spacecraft modeling, attitude determination, and control : quaternion-based approach / Yaguang Yang (US Nuclear Regulatory Commission, Office of Research, Rockville, Maryland, USA).
Material type:
TextPublisher: Boca Raton, FL : CRC Press, 2019Description: 1 online resourceContent type: text Media type: computer Carrier type: online resourceISBN: 9780429446580; 0429446586; 9780429822131; 0429822138; 9780429822124; 042982212X; 9780429822148; 0429822146Subject(s): Space vehicles -- Attitude control systems | Stability of space vehicles | Rotational motion (Rigid dynamics) | Quaternions | Vector analysis | TECHNOLOGY & ENGINEERING / Engineering (General) | TECHNOLOGY / Engineering / Mechanical | TECHNOLOGY / Industrial Design / GeneralDDC classification: 629.47/42 LOC classification: TL3260 | .Y36 2019ebOnline resources: Taylor & Francis | OCLC metadata license agreement "A science publishers book."
Introduction -- Orbit dynamics and properties -- Rotational sequences and quaternion -- Spacecraft dynamics and modeling -- Space environment and disturbance torques -- Spacecraft attitude determination -- Astronomical vector measurements -- Spacecraft attitude estimation -- Spacecraft attitude control -- Spacecraft actuators -- Spacecraft control using magnetic torques -- Attitude maneuver and orbit-raising -- Attitude mpc control -- Spacecraft control using cmg -- Spacecraft rendezvous and docking.
This book discusses all spacecraft attitude control-related topics: spacecraft (including attitude measurements, actuator, and disturbance torques), modeling, spacecraft attitude determination and estimation, and spacecraft attitude controls. Unlike other books addressing these topics, this book focuses on quaternion-based methods because of its many merits. The book lays a brief, but necessary background on rotation sequence representations and frequently used reference frames that form the foundation of spacecraft attitude description. It then discusses the fundamentals of attitude determination using vector measurements, various efficient (including very recently developed) attitude determination algorithms, and the instruments and methods of popular vector measurements. With available attitude measurements, attitude control designs for inertial point and nadir pointing are presented in terms of required torques which are independent of actuators in use. Given the required control torques, some actuators are not able to generate the accurate control torques, therefore, spacecraft attitude control design methods with achievable torques for these actuators (for example, magnetic torque bars and control moment gyros) are provided. Some rigorous controllability results are provided. The book also includes attitude control in some special maneuvers, such as orbital-raising, docking and rendezvous, that are normally not discussed in similar books. Almost all design methods are based on state-spaced modern control approaches, such as linear quadratic optimal control, robust pole assignment control, model predictive control, and gain scheduling control. Applications of these methods to spacecraft attitude control problems are provided. Appendices are provided for readers who are not familiar with these topics.
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