Open AccessJournal Article
Global Positioning System : Theory and Applications I
TLDR
Differential GPS and Integrity Monitoring differential GPS Pseudolites Wide Area Differential GPS Wide Area Augmentation System Receiver Autonomous Integrity Monitoring Integrated Navigation Systems Integration of GPS and Loran-C GPS and Inertial Integration Receiver Aut autonomous Integrity Monitoring Availability for GPS Augmented with Barometric Altimeter Aiding and Clock CoastingAbstract:
Differential GPS and Integrity Monitoring Differential GPS Pseudolites Wide Area Differential GPS Wide Area Augmentation System Receiver Autonomous Integrity Monitoring Integrated Navigation Systems Integration of GPS and Loran-C GPS and Inertial Integration Receiver Autonomous Integrity Monitoring Availability for GPS Augmented with Barometric Altimeter Aiding and Clock Coasting GPS and Global Navigation Satellite System (GLONASS) GPS Navigation Applications Land Vehicle Navigation and Tracking Marine Applications Applications of the GPS to Air Traffic Control GPS Applications in General Aviation Aircraft Automatic Approach and Landing Using GPS Precision Landing of Aircraft Using Integrity Beacons Spacecraft Attitude Control Using GPS Carrier Phase Special Applications GPS for Precise Time and Time Interval Measurement Surveying with the Global Position System Attitude Determination Geodesy Orbit Determination Test Range Instrumentation.read more
Citations
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Full-scale structural monitoring using an integrated GPS and accelerometer system
TL;DR: In this paper, an integrated system comprising of RTK-GPS and accelerometers has been developed with the objective of assessing full-scale structural responses by exploiting the complementary characteristics of GPS and accelerometer sensors.
A novel channel model for land mobile satellite navigation
TL;DR: The usability for both navigation systems (GPS as well as GALILEO) is given and video recordings taken during the measurements combined with the channel impulse response, Doppler delay spectrum and geometrical information are presented.
Journal ArticleDOI
A 115-mW, 0.5-/spl mu/m CMOS GPS receiver with wide dynamic-range active filters
D.K. Shaeffer,A. Shahani,S.S. Mohan,H. Samavati,H.R. Rategh,M. del Mar Hershenson,Min Xu,Chik Patrick Yue,D.J. Eddleman,Thomas H. Lee +9 more
TL;DR: In this paper, the authors present a 115mW Global Positioning System radio receiver that is implemented in a 0.5/spl mu/m CMOS technology, which includes the complete analog signal path, comprising a low-noise amplifier, I-Q mixers, on-chip active filters, and 1-bit analog-digital converters.
Journal ArticleDOI
Position and orientation in ad hoc networks
Dragos Niculescu,Badri Nath +1 more
TL;DR: It is shown how position and orientation of all the nodes in a connected ad hoc network can be determined with a small fraction of landmarks that can position/orient themselves, given that all nodes have some combination of local capabilities.
Use of the Correct Satellite Repeat Period to Characterize and Reduce Site-Specific Multipath Errors
TL;DR: In this article, the authors provide an overview of multipath effects on code, SNR, and carrier phase measurements including expressions to estimate distance to the reflector for simple geometries.
References
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Wide Area Differential GPS
TL;DR: Simulation results indicate that normal GPS positioning errors can potentially be reduced by more than 95% using WADGPS.
Ephemeris and Clock Navigation Message Accuracy
J. Zumberge,W. Bertiger +1 more
TL;DR: The accuracy of the ephemeris and clock corrections contained in the GPS navigation message is discussed.
GPS and Inertial Integration
TL;DR: This chapter devotes one section to address each of the following questions: how complex are the integration algorithms required to provide the desired level of performance, with options for growth to meet future requirements?
Test Range Instrumentation
TL;DR: In the early 1970s, laser trackers became available to support test activities as discussed by the authors, and a combination of radar, distance-measuring equipment (DME), optical trackers such as cinetheodolites, and other miscellaneous instrumentation to provide time-space position information (TSPI) to satisfy test platform positioning requirements.