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Fundamentals of Aerospace Navigation and Guidance (Cambridge Aerospace Series, Series Number 40)

Product ID : 17041755


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About Fundamentals Of Aerospace Navigation And Guidance

Product Description This text covers fundamentals used in the navigation and guidance of modern aerospace vehicles, in both atmospheric and space flight. It can be used as a textbook supporting a graduate level course on aerospace navigation and guidance, a guide for self-study, or a resource for practicing engineers and researchers. It begins with an introduction that discusses why navigation and guidance ought to be considered together and delineates the class of systems of interest in navigation and guidance. The book then presents the necessary fundamentals in deterministic and stochastic systems theory and applies them to navigation. Next, the book treats optimization and optimal control for application in optimal guidance. In the final chapter, the book introduces problems where two competing controls exercise authority over a system, leading to differential games. Fundamentals of Aerospace Navigation and Guidance features examples illustrating concepts and homework problems at the end of all chapters. Review "The theory and applications of optimization and optimal guidance are well presented, followed by an interesting section on differential game theory accompanied by several classical examples … The authors develop the equations for various problems in navigation and guidance to lead readers through the necessary thought process to develop their applications … This book is appropriate for seniors, graduate students, or professionals wanting to gain an understanding of these complex topics." D. B. Spencer, Choice 'It is a pleasure for me to review this book written by [Professor] Kabamba and [Professor] Girard, and, as a former Ph.D. student of the late [Professor] Kabamba, it is also an honor … The material is presented in quintessential Kabamba fashion: simple and elegant. The key ideas are outlined very clearly at the end of every chapter so that the reader does not get lost in the details of the treatment … this book is an important addition to the topic of applied modern control systems, especially given the push toward greater autonomy for robotic systems in the near future. The authors have done an admirable job of piecing together the most important results from linear systems and optimal control theory in a clear and compact fashion and have shown the power of these methods via their application to aerospace navigation and guidance.' Suman Chakravorty, IEEE Systems Control Magazine Book Description This text covers fundamentals in navigation of modern aerospace vehicles. It is an excellent resource for both graduate students and practicing engineers. About the Author Pierre T. Kabamba is a Professor of Aerospace Engineering at the University of Michigan. Professor Kabamba's research interests include linear and nonlinear dynamic systems, robust control, guidance and navigation, and intelligent control. His recent research activities are aimed at the development of a quasilinear control theory that is applicable to linear plants with nonlinear sensors or actuators. He has also done work in the design, scheduling, and operation of multi-spacecraft interferometric imaging systems used to obtain images of exosolar planets. Moreover, he has also done work in the analysis and optimization of random search algorithms. Finally, he is also doing work in simultaneous path planning and communication scheduling for unmanned aerial vehicles (UAVs) under the constraint of radar avoidance. He is author or co-author of more than 170 publications featured in refereed journals and conferences and of numerous book chapters. Professor Anouck Girard's interests include nonlinear control and systems engineering with applications in unmanned vehicle systems; hybrid, distributed, and embedded systems; maneuver coordination; and control of vehicles and mobile ground, air, and ocean robots. She is the director of the Aerospace Robotics and Control (ARC) Laboratory, in which cooperative control algorithms are developed a