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MAB
Automatic Control of Atmospheric and Space Flight Vehicles: Design and Analysis with MATLAB® and Simulink®
Kategorie
Beschreibung
036a
XD-US‡XA-CH
037b
eng
077a
350822093 Buchausg. u.d.T.: ‡Tewari, Ashish: Automatic control of atmospheric and space flight vehicles
087q
978-0-8176-4863-3
100
Tewari, Ashish
331
Automatic Control of Atmospheric and Space Flight Vehicles
335
Design and Analysis with MATLAB® and Simulink®
410
Boston
412
Springer Science+Business Media, LLC
425
2011
425a
2011
433
Online-Ressource (XIV, 374p. 163 illus, digital)
451b
Control Engineering
501
Includes bibliographical references and index
517
Automatic Control of Atmospheric and Space Flight Vehicles; Preface; Contents; Chapter 1Introduction; 1.1 Aims and Objectives; 1.2 Control System; 1.3 Plant Model; 1.4 Properties of a System; 1.4.1 Stability in the Sense of Lyapunov; 1.4.2 Controllability and Observability; 1.5 Automatic Controllers; 1.5.1 Terminal and Tracking Control; 1.5.2 Control System Performance; 1.6 Linear Systems; 1.6.1 Solution of Linear State Equations; 1.6.2 Linear Time-Invariant Systems; 1.6.3 Linear Stability Criteria; 1.6.4 Controllability of Linear Systems; 1.6.5 Observability of Linear Systems. 1.7 Aerospace Vehicle Guidance and Control1.8 Summary; Exercises; Chapter 2Flight Dynamic Models; 2.1 Aims and Objectives; 2.2 Rigid Body Dynamics; 2.3 Attitude Kinematics; 2.3.1 Euler Angles; 2.3.2 Quaternion; 2.4 Flight Dynamics; 2.4.1 Translational Kinematics in Planet-Fixed Frame; 2.4.2 Attitude Flight Dynamics; 2.5 Flight Dynamics System; 2.6 Space Flight Dynamics; 2.6.1 Orbital Mechanics; 2.6.1.1 Kepler's Equation; 2.6.1.2 Celestial Frame of Reference; 2.6.2 Spacecraft Attitude Dynamics; 2.7 Atmospheric Flight Dynamics; 2.7.1 Wind Axes; 2.7.2 Aerodynamic Forces and Moments. 2.7.2.1 Stability Axes, Small Perturbations, and Control Surfaces2.8 Flight Sensors; 2.8.1 Gyrodynamics; 2.8.1.1 Rate Gyro; 2.8.1.2 Rate-Integrating (Displacement) Gyro; 2.8.1.3 Two-Degree-of-Freedom Gyroscope; 2.8.2 Inertial Measurement Units; 2.9 Summary; Exercises; Chapter 3Control Design Techniques; 3.1 Aims and Objectives; 3.2 Transfer Function and Singularity Inputs; 3.2.1 Impulse Response; 3.2.2 Step Response; 3.2.3 Frequency Response; 3.3 Single Variable Design; 3.3.1 Steady-State Error; 3.3.2 Proportional-Integral-Derivative Control. 3.3.2.1 Roll Autopilot for Aircraft and Banking Missiles3.3.3 Feedforward/Feedback Tracking; 3.3.4 Robustness Analysis from Frequency Response; 3.3.4.1 Lead and Lag Compensation for Robust Design; 3.4 Multivariable Control Design; 3.4.1 Regulator Design by Eigenstructure Assignment; 3.4.2 Linear, Quadratic Regulator; 3.4.2.1 Frozen LQR Design for a Time-Varying Plant; 3.4.3 Linear Observers and Output Feedback Compensators; 3.4.3.1 Full-Order Observer; 3.4.3.2 Reduced-Order Observer; 3.4.4 Linear, Quadratic, Gaussian (LQG) Compensator; 3.5 Digital Control System; 3.6 Summary; Exercises. Chapter 4Automatic Control of Aircraft4.1 Aims and Objectives; 4.2 Aircraft Dynamics; 4.2.1 Rotational Kinematics; 4.2.2 Translational Kinetics; 4.2.3 Rotational Kinetics; 4.3 Longitudinal Stability and Control; 4.3.1 Longitudinal Stability Derivatives; 4.3.1.1 Speed Derivatives; 4.3.1.2 Static Stability Derivatives; 4.3.1.3 Pitch Derivatives; 4.3.1.4 Aerodynamic Inertia Derivatives; 4.3.2 Longitudinal Modes; 4.3.2.1 Nondimensional Longitudinal Dynamics (Controls Fixed); 4.3.3 Longitudinal Control; 4.3.3.1 Elevator Servo; 4.3.3.2 Engine Servo; 4.3.3.3 Aircraft Plant for Longitudinal Control. 4.4 Automatic Longitudinal Control
527
Buchausg. u.d.T.: ‡Tewari, Ashish: Automatic control of atmospheric and space flight vehicles
540a
ISBN 978-0-8176-4864-0
700
|TJFM
700
|TEC004000
700
|*93-02
700
|93-04
700b
|629.8
700b
|629.1/1
700b
|629.1/1
700c
|TJ212-225
700g
1271570009 ZO 8000
700g
127098828X ZQ 5000
750
Automatic Control of Atmospheric and Space Flight Vehicles is perhaps the first book on the market to present a unified and straightforward study of the design and analysis of automatic control systems for both atmospheric and space flight vehicles. Covering basic control theory and design concepts, it is meant as a textbook for senior undergraduate and graduate students in modern courses on flight control systems. In addition to the basics of flight control, this book covers a number of upper-level topics and will therefore be of interest not only to advanced students, but also to researcher
902s
209202319 Regelungstechnik
902s
212874357 SIMULINK
907s
209202319 Regelungstechnik
907s
211297240 MATLAB
012
35022868X
081
Tewari, Ashish <P>: Automatic Control of Atmospheric and Space Flight Vehicles
100
Springer E-Book
125a
Elektronischer Volltext - Campuslizenz
655e
$uhttp://dx.doi.org/10.1007/978-0-8176-4864-0
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