Dr. Xuefeng Li is currently Professor, Ph.D. advisor at Beijing Aerospace Automatic Control Institute. He graduated from Northwestern Polytechnical University with master’s and doctor’s degree of aircraft control, guidance and simulation in 1993 and 1996, repectively. At present, he holds the position of chief designer of national key project - "large launch vehicle control system", and chief designer of the upper stage model control system of the Expedition series, deputy director of the state key laboratory of astronautics intelligent control technology, academic leaders of China Aerospace Science and Technology Corporation, chief expert of China Academy of Launch Vehicle Technology (CALT). For years, he had been engaging in aircraft control, guidance and integrated design. His research field mainly involved navigation and guidance, attitude control, integrated circuit of control system and ground launching system. He presided over completion of projects including Research on Intelligent Potential Analysis Technology of Aerospace Control System and Demonstration of Development Program of Civil Aerospace Pre-research Advanced Upper Stage Control System sponsored by China National Natural Science Foundation. Prof. Li has published nearly 20 academic papers on domestic key academic journals, obtained 30 national defense patents, and a number of awards including Ministerial and Provincial-level Science and Technology Progress, and Military Science and Technology Progress Award. In 2004, he was awarded with Young & Middle-aged Experts of Outstanding Contribution in National Defense Industry. In 2005, he received State Council Special Allowance by the Chinese Government and in 2008 received China Space Foundation Award.

Mr. Chaobing Li is senior engineer of Beijing Aerospace Automatic Control Institute. He received his MS degree from Peking University in 2007. At present, he holds the position of chief designer of

This book uses the entire flying process, starting from ground launching of the orbital transfer vehicle (OTV) to injecting payload into earth synchronous orbit, as an example for real-world engineering practices. It discusses in detail the analysis design and integrated OTV navigation and guidance system technologies in combination with the engineering experiences of the authors in analysis, design and integrated OTV navigation and guidance system applications, and the research on navigation and guidance theories. It focuses on establishing motion of air vehicle equations, control system hardware components, orbit prediction technology, inertial navigation and initial alignment technologies, INS/GNSS integrated navigation technologies, INS/CNS integrated navigation technologies, redundant fault tolerance and failure reconfiguration technology of inertial sensors, guidance and midcourse correction technologies and orbit control strategies.

The book is a valuable reference book for the engineers, technicians and researchers who are engaged in analysis, design and integrated application of OTV navigation and guidance control systems. It can also be used as teaching material for postgraduates and senior undergraduates majoring in OTV navigation and guidance systems and other related subjects.