Synopses & Reviews
Here a leading researcher provides a comprehensive treatment of the design of automatic control logic for spacecraft and aircraft. In this book Arthur Bryson describes the linear-quadratic-regulator (LQR) method of feedback control synthesis, which coordinates multiple controls, producing graceful maneuvers comparable to those of an expert pilot.
The first half of the work is about attitude control of rigid and flexible spacecraft using momentum wheels, spin, fixed thrusters, and gimbaled engines. Guidance for nearly circular orbits is discussed. The second half is about aircraft attitude and flight path control. This section discusses autopilot designs for cruise, climb-descent, coordinated turns, and automatic landing. One chapter deals with controlling helicopters near hover, and another offers an introduction to the stabilization of aeroelastic instabilities. Throughout the book there is a strong emphasis on the mathematical modeling necessary for designing a good feedback control system. The appendixes summarize analysis of linear dynamic systems, synthesis of analog and digital feedback control, simulation, and modeling of flexible vehicles.
Review
"The text reads very smoothly, and I found it very well edited. . . . I very much enjoyed reading it and find it a welcome addition to the available dynamics and control texts."--American Scientist
Review
The text reads very smoothly, and I found it very well edited. . . . I very much enjoyed reading it and find it a welcome addition to the available dynamics and control texts. American Scientist
Synopsis
Here a leading researcher provides a comprehensive treatment of the design of automatic control logic for spacecraft and aircraft. In this book Arthur Bryson describes the linear-quadratic-regulator (LQR) method of feedback control synthesis, which coordinates multiple controls, producing graceful maneuvers comparable to those of an expert pilot.
The first half of the work is about attitude control of rigid and flexible spacecraft using momentum wheels, spin, fixed thrusters, and gimbaled engines. Guidance for nearly circular orbits is discussed. The second half is about aircraft attitude and flight path control. This section discusses autopilot designs for cruise, climb-descent, coordinated turns, and automatic landing. One chapter deals with controlling helicopters near hover, and another offers an introduction to the stabilization of aeroelastic instabilities. Throughout the book there is a strong emphasis on the mathematical modeling necessary for designing a good feedback control system. The appendixes summarize analysis of linear dynamic systems, synthesis of analog and digital feedback control, simulation, and modeling of flexible vehicles.
Description
Includes bibliographical references (p. [369-375]) and index.
Table of Contents
| List of Figures | |
| List of Tables | |
| Preface and Acknowledgments | |
Ch. 1 | Natural Motions of Rigid Spacecraft | 1 |
Ch. 2 | Spacecraft Sensors and Attitude Determination | 16 |
Ch. 3 | Attitude Control with Thrusters | 28 |
Ch. 4 | Attitude Control with Reaction Wheels | 37 |
Ch. 5 | Attitude Stabilization with Spin | 50 |
Ch. 6 | Attitude Control with a Gimbaled Momentum Wheel | 74 |
Ch. 7 | Attitude Control during Thrust Maneuvers | 93 |
Ch. 8 | Control of Translational Motions | 102 |
Ch. 9 | Flexibility and Fuel Slosh | 114 |
Ch. 10 | Natural Motions of Rigid Aircraft | 142 |
Ch. 11 | Aircraft Sensors | 164 |
Ch. 12 | Control of Longitudinal Motions of Aircraft | 179 |
Ch. 13 | Control of Lateral Motions of Aircraft | 232 |
Ch. 14 | Control of Helicopters near Hover | 271 |
Ch. 15 | Aeroelastic Systems | 284 |
| Appendix A - Linear System Representations | 301 |
| Appendix B - Steady-State Control | 311 |
| Appendix C - Synthesis of Analog Control Logic | 317 |
| Appendix D - Synthesis of Digital Control Logic | 328 |
| Appendix E - Simulation | 343 |
| Appendix F - Modeling Flexible Systems | 350 |
| References | 369 |
| Index | 377 |