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==[[GPS Reference Frame| GPS Reference Frame]]== | ==[[GPS Reference Frame| GPS Reference Frame]]== | ||
Accurate and well-defined Time References and Coordinate Frames are essential in [[GNSS|GNSS]], where positions are computed from signal travel time measurements and provided as a set of coordinates. | Accurate and well-defined Time References and Coordinate Frames are essential in [[GNSS|GNSS]], where positions are computed from signal travel time measurements and provided as a set of coordinates. | ||
GPS uses the World Geodetic System WGS-84,<ref name="GNSS-Book ">J. Sanz Subirana, JM. Juan Zornoza and M. Hernández-Pajares, ''Global Navigation Satellite Systems: | GPS uses the World Geodetic System WGS-84,<ref name="GNSS-Book ">J. Sanz Subirana, JM. Juan Zornoza and M. Hernández-Pajares, ''Global Navigation Satellite Systems: Volume I: Fundamentals and Algorithms''</ref> developed by The US Defence Department, which is a unified terrestrial reference system for position and vector referencing. Indeed, the GPS broadcast ephemeris are linked to the position of the satellite antenna phase centre in the WGS-84 reference frame. Thus, the user receiver coordinates will be expressed in the same ECEF frame. | ||
Volume I: Fundamentals and Algorithms''</ref> developed by The US Defence Department, which is a unified terrestrial reference system for position and vector referencing. Indeed, the GPS broadcast ephemeris are linked to the position of the satellite antenna phase centre in the WGS-84 reference frame. Thus, the user receiver coordinates will be expressed in the same ECEF frame. | |||
GPS System Time (GPST) is defined by the [[GPS Ground segment| GPS Ground segment]] on the basis of a set of atomic clocks aboard the satellites and in the Monitor Stations. It is not adjusted for leap seconds and it is synchronized with the UTC (USNO) at nanosecond level. | GPS System Time (GPST) is defined by the [[GPS Ground segment| GPS Ground segment]] on the basis of a set of atomic clocks aboard the satellites and in the Monitor Stations. It is not adjusted for leap seconds and it is synchronized with the UTC (USNO) at nanosecond level. | ||
The origin epoch of GPS time is 0h UTC (midnight) of January 5th to 6th of 1980. | The origin epoch of GPS time is 0h UTC (midnight) of January 5th to 6th of 1980. |
Revision as of 16:18, 31 March 2011
GPS | |
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Title | GPS General Introduction |
Author(s) | GMV |
Level | Basic |
Year of Publication | 2011 |
The GPS is a space-based global navigation satellite system (GNSS) that provides reliable positioning, navigation, and timing services to civilian and military users on a continuous worldwide basis.
GPS receivers compute their position in the GPS Reference System using satellite technology and based on triangulation principles (please refer to GNSS positioning).
GPS was originally developed for the U.S. military, but very early in the experimental phase of GPS the incident with the Korean Air Lines Flight 007[1] lead the US Government to decide to make GPS use free for civilian purposes[2]
Deployment of the GPS system began on 22 February 1978 with the launch of the first Block I Navstar GPS satellite.[3] Initial Operating Capability was declared in December 1993 with 24 operational GPS satellites in orbit. Full Operational Capability was declared in June of 1995.
GPS is maintained by the United States government and is freely accessible by anyone with a GPS receiver. The Department of Defense is responsible for operating the system, but it also receives national-level attention and guidance through the National Executive Committee for Space-Based Positioning, Navigation, and Timing (PNT).[4]
GPS Signal Structure
GPS satellites transmit right-hand circularly polarized signals to the earth at two frequencies, designated L1 and L2. The main GPS carrier signal L1, at 1575.42MHz, is modulated by two codes: the coarse/acquisition (C/A) code also known as civilian code and the precision/secure (P/Y) code, reserved by cryptographic techniques to military and authorized civilian users. The GPS L2 signal, centered at 1227.6 MHz, only contains the precise code and it was established to provide a second frequency for ionospheric group delay correction.
The GPS modernization program began in 2005 with the launch of the first IIR-M satellite. Since that moment on, two new signals are transmitted: L1C for civilian users and a new military signal (M code) in L1 and L2 to provide better jamming resistance than the Y code [5].
Moreover, a new radio frequency link (L5 at 1176.45 MHz) for civilian users has been included. This signal, available since the launch of the Block IIF satellites (May 28th 2010) will be compatible with other GNSS systems.
GPS Reference Frame
Accurate and well-defined Time References and Coordinate Frames are essential in GNSS, where positions are computed from signal travel time measurements and provided as a set of coordinates. GPS uses the World Geodetic System WGS-84,[6] developed by The US Defence Department, which is a unified terrestrial reference system for position and vector referencing. Indeed, the GPS broadcast ephemeris are linked to the position of the satellite antenna phase centre in the WGS-84 reference frame. Thus, the user receiver coordinates will be expressed in the same ECEF frame. GPS System Time (GPST) is defined by the GPS Ground segment on the basis of a set of atomic clocks aboard the satellites and in the Monitor Stations. It is not adjusted for leap seconds and it is synchronized with the UTC (USNO) at nanosecond level. The origin epoch of GPS time is 0h UTC (midnight) of January 5th to 6th of 1980.
GPS Services
GPS provides two levels of service, Standard Positioning Service and the Precise Positioning Service: The Standard Positioning Service (SPS),[7] is a positioning and timing service provided on GPS L1 frequency and available to all GPS users. The L1 frequency contains a coarse acquisition (C/A) code and a navigation data message. The Precise Positioning Service (PPS),[8] is a highly accurate military positioning, velocity and timing service broadcasted at the GPS L1 and L2 frequencies. Both frequencies contain a precision (P) code ranging signal with a navigation data message that is reserved for authorized use by the use of cryptography.
GPS Architecture
GPS is comprised of three segments: a GPS Space Segment (SS), a GPS Ground Segment (CS), and a GPS User Segment (U.S.). The main functions of the GPS Space Segment are to generate and transmit code and carrier phase signals, and to store and retransmit the navigation message sent by the GPS Ground Segment. The GPS Ground Segment is composed of a master control station, a network of monitor stations and 4 ground antennas which upload the clock and orbit errors, as well as the navigation data message to the GPS satellites. Finally, the GPS User Segment consists on the millions of receivers performing the navigation, timing or other related functions.
Differential GPS
Differential GPS is an enhancement to primary GPS constellation(s) information by the use of a network of ground-based reference stations which enable the broadcasting of differential information to the user – also named rover – to improve the accuracy of his position – the integrity is not assured. There are several differential GNSS techniques, such as the classical DGPSS (or DGPS), the Real Time Kinematic (RTK) and the Wide Area RTK (WARTK).
GPS Performances
The levels of performance that the user can expect from GPS are specified in the Standard Positioning Service Performance Standard,[7] and the Precise Positioning Standard[8], However, the values provided by these documents are very conservative, being the actual performances usually better than these official values. Moreover, the performance obtained with GPS depends strongly on the mode of operation. For instance, a stand-alone receiver that uses only the signals received from the satellites, the levels of performance are:[9]
- C/A-code receivers ~ 5 -10 m.
- P/Y-code receivers ~ 2 -9 m
In case of using GPS in a differential mode, the performances that can be expected are:
- C/A-code DGPS receivers ~0.7 -3 m.
- P/Y-code DGPS receivers ~0.5 -2.0 m.
GPS Future and Evolutions
Aimed at improving the performance for civilian users, the GPS modernization will introduce the following signals:[10]
- L2C (1227.6 MHz: It enables the development of dual-frequency civil GPS receivers to correct the ionospheric time delay error. This signal is available since 2005, with the launch of the first IIR-M satellite.[11]
- L5 (1176.45 MHz): It will be compatible with other GNSS systems and will transmit at a higher power than current civil GPS signals, and have a wider bandwidth. This signal is available since the launch of the Block IIF satellites (May 28th 2010).
- L1C (1575.42 MHz): Designed for interoperability with Galileo, it will be backward compatible with the current civil signal on L1
Moreover, in order to improve the anti-jamming and secure access of the military GPS signals, a new military signal (M-code) will be transmitted in L1 and L2 frequencies. Regarding the Ground Segment, the new Operational Control Segment (OCX) will replace the current GPS Operational Control System placed at Schriever Air Force Base.[12][13] The OCX will maintain backwards compatibility with the Block IIR and IIR-M constellation satellites, providing command and control of the new GPS IIF and GPS III families of satellites, and enabling new modernized civil signal capabilities.
Notes
References
- ^ Korean Air Lines Flight 007
- ^ Global Positioning System on Wikipedia
- ^ Block 1 Satellite Information
- ^ Federal Agencies
- ^ Barker, Capt. Brian C.; Betz,, John W.; Clark, John E.; Correia, Jeffrey T.; Gillis, James T.; Lazar, Steven; Rehborn, Lt. Kaysi A.; Straton, III,, John R..
- ^ J. Sanz Subirana, JM. Juan Zornoza and M. Hernández-Pajares, Global Navigation Satellite Systems: Volume I: Fundamentals and Algorithms
- ^ a b Global Positioning Sys-tem Standard Positioning Service Performance Standard
- ^ a b Global Positioning Sys-tem Precise Positioning Service Performance Standard
- ^ The Modernization of GPS: Plans, New Capabilities and the Future Relationship to Galileo, Keith D. McDonald
- ^ http://www.pnt.gov/public/docs/2006/modernization.pdf GPS Modernization Fact Sheet]
- ^ [ http://scpnt.stanford.edu/pnt/PNT10/presentation_slides/2-PNT_Symposium_Gruber.pdf GPS Modernization and Program Update, Bernie Grube r]
- ^ [ http://www.pnt.gov/advisory/2010/10/canty.pdf GPS OCX Update]
- ^ [ http://gps.gov/congress/newsletter/2010/04.pdf OCS contract awarded]