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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Journal ArticleDOI
Real time orbit determination using GPS navigation solution
TL;DR: This work analyses a real time orbit estimator using the raw navigation solution provided by GPS receivers, which considers a Kalman filter with a rather simple orbit dynamic model and random walk modeling of the receiver clock bias and drift.
Journal ArticleDOI
Performance evaluation of IRI-2007 at equatorial latitudes and its Matlab version for GNSS applications
TL;DR: The source code of the Fortran based IRI-2007 is converted into Matlab and validated and the vertical delay results over the equatorial region derived from IRI and GPS data of three IGS stations are compared.
Journal ArticleDOI
Investigation of Best Satellite---Receiver Geometry to Improve Positioning Accuracy Using GPS and IRNSS Combined Constellation over Hyderabad Region
TL;DR: By investigating the DOP with GPS and IRNSS combined constellations; it is possible to obtain the improved positioning accuracy that is sparingly useful for precision applications such as CAT-1 aircraft landings, surveying and disaster management.
Proceedings ArticleDOI
INS/GPS/Pseudolite integrated navigation for land vehicle in urban canyon environments
Wang Wei,Liu Zongyu,Xie Rongrong +2 more
TL;DR: A pseudolite-augmented scheme is proposed, and a modified measurement model is presented, which uses the double difference of measured pseudo-ranges and INS estimated ranges to solve the urban canyon problem successfully.
IADIRA: Inertial Aided Deeply Integrated Receiver Architecture
P.F. da Silva,Jorge Sa Silva,Augusto Caramagno,Mariano Wis,M. Eulàlia Parés,Ismael Colomina,Antonio Fernández,José Diez,V. Gabaglio +8 more
TL;DR: In this paper, the authors present results of how MEMS Miniature Inertial Measurement Units can be seamless and transparently integrated into GNSS receiver antennas through an tightly coupled or deeply integrated architecture.
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.