Details

<p><b>Part A: Satellite Navigation Systems</b></p> <p><b>1. Introduction, Early History, and Assuring PNT (PTA)<br /></b><i>Bradford W. Parkinson, Stanford University, US</i><br /><i>Y. T. Jade Morton, University of Colorado Boulder, US</i><br /><i>Frank van Diggelen, Google, US</i><br /><i>James J. Spilker Jr., Stanford University, US</i></p> <p><b>2. Fundamentals of Satellite-Based Navigation and Timing<br /></b><i>John W. Betz, the Mitre Corporation, US</i></p> <p><b>3. The Navstar Global Positioning System<br /></b><i>John W. Betz, the Mitre Corporation, US</i></p> <p><b>4. GLONASS<br /></b><i>Sergey Karutin, PNT Center, Russia</i><br /><i>N. Testoedov, PNT Center, Russia</i><br /><i>A. Tyulin, PNT Center, Russia</i><br /><i>Alexei Bolkunov, PNT Center, Russia</i></p> <p><b>5. Galileo<br /></b><i>José Ángel Ávila Rodríguez, European Space Agency, the Netherlands</i><br /><i>Jörg Hahn, European Space Agency, the Netherlands</i><br /><i>Miguel Manteiga Bautista, European Space Agency, the Netherlands</i><br /><i>Eric Châtre, European Commission, Belgium</i></p> <p><b>6. Beidou Navigation Satellite System<br /></b><i>Mingquan Lu, Tsinghua University, China</i><br /><i>Zheng Yao, Tsinghua University, China</i></p> <p><b>7. The India Regional Navigation Satellite System<br /></b><i>Vyasaraj Rao, Accord Software and Systems, India</i></p> <p><b>8. Quasi-Zenith Satellite System<br /></b><i>Satoshi Kogure, National Space Policy Secretariat, Japan</i><br /><i>Yasuhiko Kawazu, National Space Policy Secretariat, Japan</i><br /><i>Takeyasu Sakai, National Institute of Maritime, Port, and Aviation Technology, Japan</i></p> <p><b>9. GNSS Interoperability: Purpose, Process, Progress, and Myths<br /></b><i>Thomas A. Stansell, Jr.,  Stansell Consulting, US</i></p> <p><b>10. Signal Quality Monitoring<br /></b><i>Frank van Graas, Ohio University, US</i><br /><i>Sabrina Ugazio, Ohio University, US</i></p> <p><b>11. GNSS Orbit Determination and Time Synchronization<br /></b><i>Oliver Montenbruck, German Aerospace Center, Germany</i><br /><i>Peter Steigenberger, German Aerospace Center, Germany</i></p> <p><b>12. Ground-Based Augmentation Systems for Aviation Applications<br /></b><i>Boris Pervan, Illinois Institute of Technology, US</i></p> <p><b>13. Satellite-Based Augmentation Systems <br /></b><i>Todd Walter, Stanford University, US</i></p> <p><b>Part B: Satellite Navigation Technologies</b></p> <p><b>14. GNSS Receivers: An Overview<br /></b><i>Sanjeev Gunawardena, Air Force Institute of Technology, US</i><br /><i>Y. T. Jade Morton, University of Colorado Boulder, US</i></p> <p><b>15. GNSS Receiver Signal Tracking<br /></b><i>Y. T. Jade Morton, University of Colorado Boulder, US</i><br /><i>Rong Yang, Shanghai Jiaotong University, China</i><br /><i>Brian Breitsch, University of Colorado Boulder, US</i></p> <p><b>16. Vector Processing<br /></b><i>Matthew V. Lashley, Auburn University, US</i><br /><i>Scott Martin, Georgia Tech Research Institute, US</i><br /><i>James Sennott, Tracking and Imaging Systems, US</i></p> <p><b>17. Assisted GNSS<br /></b><i>Frank van Diggelen, Google, US</i></p> <p><b>18. High Sensitivity GNSS<br /></b><i>Frank van Diggelen, Google, US</i></p> <p><b>19. Relative Positioning and RTK<br /></b><i>Sunil Bisnath, York University, Canada</i></p> <p><b>20. GNSS Precise Point Positioning <br /></b><i>Peter Teunissen, Curtin University, Australia</i></p> <p><b>21. Direction Position Estimation<br /></b><i>Pau Closas, Northeastern University, US</i><br /><i>Grace Gao, Stanford University, US</i></p> <p><b>22. Robust Positioning in the Presence of Multipath and NLOS GNSS Signals<br /></b><i>Gary A. McGraw, Rockwell Collins, US</i><br /><i>Paul D. Groves, University College London, UK</i><br /><i>Benjamin W. Ashman, National Aeronautics and Space Administration, US</i></p> <p><b>23. GNSS Integrity<br /></b><i>Sam Pullen, Stanford University, US</i><br /><i>Mathieu Joerger, Virginia Tech, US</i></p> <p><b>24. Interference, Security, and Proof of Location<br /></b><i>Logan Scott, Logan Scott Consulting, US</i></p> <p><b>25. Civilian GNSS Spoofing, Detection, and Recovery<br /></b><i>Mark Psiaki, Virginia Tech, US</i><br /><i>Todd Humphreys, University of Texas Austin, US</i></p> <p><b>26. GNSS Antenna and Antenna Array Signal Processing<br /></b><i>Andrew O’Brien, the Ohio State University, US</i><br /><i>Chi-Chih Chen, the Ohio State University, US</i><br /><i>Inder J. Gupta, the Ohio State University, US</i></p> <p><b>Part C: Satellite Navigation for Engineering and Scientific Applications</b></p> <p><b>27. Global Geodesy and Reference Frames<br /></b><i>Chris Rizos, University of New South Wales, Australia</i><br /><i>Zuheir Altamimi, Institut National de l'Information Géographique et Forestière, France</i><br /><i>Gary Johnson, Geoscience Australia, Australia</i></p> <p><b>28. GNSS Geodesy in Geophysics, Natural Hazards, Climate, and the Environment<br /></b><i>Yehuda Bock, Scripps Institution of Oceanography, US</i><br /><i>Shimon Wdowinski, Florida International University, US</i></p> <p><b>29. Distributed Time and Frequency Information<br /></b><i>Juda Levine, National Institute of Standard and Technology, US</i></p> <p><b>30. GNSS for Neutral Atmosphere and Severe Weather Monitoring<br /></b><i>Hugues Brenot, Royal Belgian Institute for Space Aeronomy, Belgium</i></p> <p><b>31. Ionospheric Effects, Monitoring, and Mitigation Techniques<br /></b><i>Y. T. Jade Morton, University of Colorado Boulder, US</i><br /><i>Brian Breitsch, University of Colorado Boulder, US</i><br /><i>Zhe Yang, University of Colorado Boulder, US</i><br /><i>Harrison Bourne, University of Colorado Boulder, US</i><br /><i>Dongyang Xu, University of Colorado Boulder, US</i><br /><i>Charles Rino, University of Colorado Boulder, US</i></p> <p><b>32. GNSS Ionosphere Observations for Monitoring and Forecasting Hazardous Events<br /></b><i>Panagiotis Vergados, Jet Propulsion Laboratory, US</i><br /><i>Attila Komjathy, Jet Propulsion Laboratory, US</i><br /><i>Xing Meng, Jet Propulsion Laboratory, US</i></p> <p><b>33. GNSS Radio Occultation<br /></b><i>Anthony Mannucci, Jet Propulsion Laboratory, US</i><br /><i>Chi O. Ao, Jet Propulsion Laboratory, US</i><br /><i>Walter Williamson, Jet Propulsion Laboratory, US</i></p> <p><b>34. GNSS Reflectometry for Earth Remote Sensing<br /></b><i>James Garrison, Purdue University, US</i><br /><i>Valery U. Zavorotny, University of Colorado and National Oceanic and Atmospheric Administration, US</i><br /><i>Alejandro Egido, Starlab Barcelona, Spain</i><br /><i>Kristine M. Larson, the University of Colorado Boulder, US</i><br /><i>Felipe Nievinski, UFRGS, Brazil</i><br /><i>Antonio Mollfulleda, Starlab Barcelona, Spain</i><br /><i>Giulio Ruffini, Starlab Barcelona, Spain</i><br /><i>Francisco Martin, Starlab Barcelona, Spain</i><br /><i>Christine Gommenginger, National Oceanography Centre, UK</i></p>

<p><b>Y. JADE MORTON, P<small>H</small>D</b> is a Professor at Ann and H. J. Smead Aerospace Engineering Sciences Department, University of Colorado at Boulder. Her research interests lie at the intersection of satellite navigation and remote sensing of the space environment, atmosphere, and Earth surface. She has led numerous research projects sponsored by AFOSR, AFRL, DARPA, NASA, NSF, ONR, and private industries. Dr. Morton is the President of the Institute of Navigation (ION), a fellow of IEEE, ION, and the Royal Institute of Navigation (RIN, UK). <p><b>FRANK VAN DIGGELEN, P<small>H</small>D</b> is a Principal Engineer at Google, where he leads the Android Core-Location Team. He also teaches at Stanford University. He is the inventor of coarse-time GNSS navigation, co-inventor of Long Term Orbits for A-GNSS, and the author of "A-GPS" the first textbook on Assisted GNSS. He is Executive Vice President of the Institute of Navigation (ION) and a Fellow of the ION and the Royal Institute of Navigation (UK). <p><b>JAMES J. SPILKER, JR., P<small>H</small>D</b> was a Consulting Professor in the Aeronautics and Astronautics Department at???Stanford University. Dr. Spilker was an elected member of the National Academy of Engineering, a Life Fellow of the IEEE, and a Fellow of the Institute of Navigation (ION). As one of the originators of GPS, James Spilker shared the Goddard Memorial Trophy and the Queen Elizabeth Prize for Engineering. <p><b>BRADFORD W. PARKINSON, P<small>H</small>D</b> is an Edward C. Wells Professor of Aeronautics and Astronautics Emeritus at Stanford University. Dr. Parkinson was the Chief Architect for GPS, led the original advocacy and development for the system, and served as the first Director of the GPS Joint Program Office. He has been the CEO of two companies and serves on many boards. Among his many awards are the IEEE Medal of Honor, the Draper Prize of the National Academy of Engineering, and the Queen Elizabeth Prize for Engineering.

<p><b>Covers the latest developments in PNT technologies, including integrated satellite navigation, sensor systems, and civil applications</b> <p>Featuring sixty-four chapters that are divided into six parts, this two-volume work provides comprehensive coverage of the state-of-the-art in satellite-based position, navigation, and timing (PNT) technologies and civilian applications. It also examines alternative navigation technologies based on other signals-of-opportunity and sensors and offers a comprehensive treatment on integrated PNT systems for consumer and commercial applications. <p><b>Volume 1</b> of <i>Position, Navigation, and Timing Technologies in the 21st Century: Integrated Satellite Navigation, Sensor Systems, and Civil Applications</i> contains three parts and focuses on the satellite navigation systems, technologies, and engineering and scientific applications. It starts with a historical perspective of GPS development and other related PNT development. Current global and regional navigation satellite systems (GNSS and RNSS), their inter-operability, signal quality monitoring, satellite orbit and time synchronization, and ground- and satellite-based augmentation systems are examined. Recent progresses in satellite navigation receiver technologies and challenges for operations in multipath-rich urban environment, in handling spoofing and interference, and in ensuring PNT integrity are addressed. A section on satellite navigation for engineering and scientific applications finishes off the volume. <b>Volume 2</b> consists of three parts and addresses PNT using alternative signals and sensors and integrated PNT technologies for consumer and commercial applications. It looks at PNT using various radio signals-of-opportunity, atomic clock, optical, laser, magnetic field, celestial, MEMS and inertial sensors, as well as the concept of navigation from Low-Earth Orbiting (LEO) satellites. GNSS-INS integration, neuroscience of navigation, and animal navigation are also covered. The volume finishes off with a collection of work on contemporary PNT applications such as survey and mobile mapping, precision agriculture, wearable systems, automated driving, train control, commercial unmanned aircraft systems, aviation, and navigation in the unique Arctic environment. In addition, this text: <ul> <li>Serves as a complete reference and handbook for professionals and students interested in the broad range of PNT subjects</li> <li>Includes chapters that focus on the latest developments in GNSS and other navigation sensors, techniques, and applications</li> <li>Illustrates interconnecting relationships between various types of technologies in order to assure more protected, tough, and accurate PNT</li> </ul> <p><i>Position, Navigation, and Timing Technologies in the 21st Century</i> will appeal to all industry professionals, researchers, and academics involved with the science, engineering, and applications of position, navigation, and timing technologies.

US