000 04174nam a22001697a 4500
999 _c44787
_d44787
003 OSt
020 _a9788126560257
082 _a629.11 TEW-A
100 _aTewari, Ashish
245 _aAdvanced Control of Aircraft Spacecraft and Rockets
260 _aNew Delhi
_bWiley
_c2011
300 _a436p.
500 _a1 Introduction 1.1 Notation and Basic Definitions 1.2 Control Systems 1.3 Guidance and Control of Flight Vehicles 1.4 Special Tracking Laws 1.5 Digital Tracking System 1.6 Summary 2 Optimal Control Techniques 2.1 Introduction 2.2 Multi-variable Optimization 2.3 Constrained Minimization 2.4 Optimal Control of Dynamic Systems 2.5 The Hamiltonian and the Minimum Principle 2.6 Optimal Control with End-Point State Equality Constraints 2.7 Numerical Solution of Two-Point Boundary Value Problems 2.8 Optimal Terminal Control with Interior Time Constraints 2.9 Tracking Control 2.10 Stochastic Processes 2.11 Kalman Filter 2.12 Robust Linear Time-Invariant Control 2.13 Summary 3 Optimal Navigation and Control of Aircraft 3.1 Aircraft Navigation Plant 3.2 Optimal Aircraft Navigation 3.3 Aircraft Attitude Dynamics 3.4 Aerodynamic Forces and Moments 3.5 Longitudinal Dynamics 3.6 Optimal Multi-variable Longitudinal Control 3.7 Multi-input Optimal Longitudinal Control 3.8 Optimal Airspeed Control 3.9 Lateral-Directional Control Systems 3.10 Optimal Control of Inertia-Coupled Aircraft Rotation 3.11 Summary 4 Optimal Guidance of Rockets 4.1 Introduction 4.2 Optimal Terminal Guidance of Interceptors 4.3 Non-planar Optimal Tracking System for Interceptors: 3DPN 4.4 Flight in a Vertical Plane 4.5 Optimal Terminal Guidance 4.6 Vertical Launch of a Rocket (Goddard's Problem) 4.7 Gravity-Turn Trajectory of Launch Vehicles 4.8 Launch of Ballistic Missiles 4.9 Planar Tracking Guidance System 4.10 Robust and Adaptive Guidance 4.11 Guidance with State Feedback 4.12 Observer-Based Guidance of Gravity-Turn Launch Vehicle 4.13 Mass and Atmospheric Drag Modeling 4.14 Summary 5 Attitude Control of Rockets 5.1 Introduction 5.2 Attitude Control Plant 5.3 Closed-Loop Attitude Control 5.4 Roll Control System 5.5 Pitch Control of Rockets 5.6 Yaw Control of Rockets 5.7 Summary 6 Spacecraft Guidance Systems 6.1 Introduction 6.2 Orbital Mechanics 6.3 Spacecraft Terminal Guidance 6.4 General Orbital Plant for Tracking Guidance 6.5 Planar Orbital Regulation 6.6 Optimal Non-planar Orbital Regulation 6.7 Summary 7 Optimal Spacecraft Attitude Control 7.1 Introduction 7.2 Terminal Control of Spacecraft Attitude 7.3 Multi-axis Rotational Maneuvers of Spacecraft 7.4 Spacecraft Control Torques 7.5 Satellite Dynamics Plant for Tracking Control 7.6 Environmental Torques 7.7 Multi-variable Tracking Control of Spacecraft Attitude 7.8 Summary Appendix A: Linear Systems A.1 Definition A.2 Linearization A.3 Solution to Linear State Equations A.4 Linear Time-Invariant System A.5 Linear Time-Invariant Stability Criteria A.6 Controllability of Linear Time-Invariant Systems A.7 Observability of Linear Time-Invariant Systems A.8 Transfer Matrix A.9 Singular Value Decomposition A.10 Linear Time-Invariant Control Design Appendix B: Stability B.1 Preliminaries B.2 Stability in the Sense of Lagrange B.3 Stability in the Sense of Lyapunov Appendix C: Control of Underactuated Flight Systems C.1 Adaptive Rocket Guidance with Forward Acceleration Input C.2 Thrust Saturation and Rate Limits (Increased Underactuation) C.3 Single- and Bi-output Observers with Forward Acceleration Input References Index
856 _uhttps://books.google.co.in/books?id=koU4lH8Xg3UC&printsec=frontcover&dq=advanced+control+of+Aircraft+spacecraft+and+rockets+by+tewari&hl=en&sa=X&ved=0ahUKEwjfg5qS8NnlAhVdk3AKHYWDB60Q6AEIKDAA#v=onepage&q=advanced%20control%20of%20Aircraft%20spacecraft%20and%20rockets%20by%20tewari&f=false
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