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GPS

GPS. Global Positioning System. Diana Cooksey, Montana State University, LRES Department. Overview. What is GPS & how does it work? Satellites Radio signals Almanacs Timing. What is GPS?. Satellites orbiting the earth Positioning, navigation and timing Operates 24 hrs/day

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GPS

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  1. GPS Global Positioning System Diana Cooksey, Montana State University, LRES Department

  2. Overview • What is GPS & how does it work? • Satellites • Radio signals • Almanacs • Timing

  3. What is GPS? • Satellites orbiting the earth • Positioning, navigation and timing • Operates 24 hrs/day • Used for any application requiring location information

  4. GPS Constellations • United States • NAVSTAR GPS (Navigation Satellite Timing & Ranging system); 28 satellites • European Union • Galileo; 30 satellites • Russia • Global Navigation Satellite System (GLONASS); 24 satellites (10 healthy)

  5. GPS Segments Space Control User

  6. Space Segment: GPS Satellites • Power • Sun-seeking solar panels • Nicad batteries • Timing • 4 atomic clocks

  7. Satellite Orbits • Orbit the earth at approx. 20,200 km (11,000 nautical miles) • Satellites complete an orbit in approximately 12 hours

  8. Satellite Signals • Radio signals, 2 frequencies • Two levels of service • Standard Positioning Service (SPS) • Precise Positioning Service (PPS)

  9. Satellite Signals • Radio signals contain • Unique pseudorandom code • Ephemeris • Clock behavior and clock corrections • System time • Status messages • Almanac

  10. Satellite Signals • Require a direct line to GPS receivers • Cannot penetrate water, soil, walls or other obstacles

  11. Satellite Almanac • Sent along with position and timing messages • Prediction of all satellite orbits • Needed to run satellite availability software • Valid for about 30 days

  12. Control Segment: US DoD Monitoring Colorado Springs Hawaii Kwajalein Ascension Diego Garcia Orbits precisely measured Discrepancies between predicted orbits (almanac) and actual orbits transmitted back to the satellites

  13. User Segment

  14. How Does GPS Work? Calculating a Position • GPS receiver calculates its position by measuring the distance to satellites (satellite ranging)

  15. Measuring Distance to Satellites • 1. Measure time for signal to travel from satellite to receiver • 2. Speed of light x travel time = distance • Distance measurements to 4 satellites are required to compute a 3-D position (latitude, longitude and altitude)

  16. Measuring Satellite Signal Travel Time • How do we find the exact time the signal left the satellite? • Synchronized codes

  17. One measurement narrows down our position to the surface of a sphere

  18. A second measurement narrows down our position to the intersection of two spheres

  19. A third measurement narrows down our position to just two points

  20. Correcting for Timing Offset • The first three measurements narrow down our position • A fourth measurement is needed to correct for timing offset (difference in synchronization between satellite and receiver clocks) • Satellites use highly accurate atomic clocks • Receivers use accurate quartz clocks

  21. 5 Things to Take Away • 3 GPS segments • Satellites transmit radio signals containing • Unique pseudorandom code • Ephemeris • Clock behavior and clock corrections • System time • Status messages • Almanac • Formula for satellite ranging (D = t ∙ v) • 4 satellites to compute an accurate 3-D position (the 4th measurement is needed to correct for timing offset) • We are not the only country with a GPS system

  22. Overview • How accurate is GPS? • Error sources • Differential correction • Accuracy levels

  23. GPS Error • Atmospheric effects • Multipath • Satellite geometry • Measurement noise (receiver error) • Ephemeris data • Satellite clock drift • Selective availability (SA)

  24. Ionospheric & Tropospheric Refraction

  25. Multipath

  26. Satellite GeometryGeometric Dilution of Precision (GDOP) • GDOP can magnify or lessen other GPS errors • Wider angles  better measurements • Components of GDOP • HDOP; H=horizontal  lat/long • VDOP; V=vertical  altitude • TDOP; T=time  clock offset PDOP values <=4 excellent 5-8 acceptable >=9 poor

  27. Dilution of Precision (DOP)

  28. Ephemeris Data • A satellite’s positions as a function of time • Each satellite broadcasts its individual ephemeris • Can contain orbital position errors

  29. Selective Availability (SA) • The accuracy of GPS signals was intentionally degraded by the DoD • SA was the largest component of GPS error • SA was turned off on May 1, 2000

  30. GPS Error Budget • Ionosphere..................................5.0 meters (0.4) • Troposphere................................0.5 meters (0.2) • Ephemeris data..............................2.5 meters (0) • Satellite clock drift........................1.5 meters (0) • Multipath....................................0.6 meters (0.6) • Measurement noise.......... ..........0.3 meters (0.3) • Selective availability.....................30-100 meters • Total.................................................~ 10 meters

  31. Differential Correction • GPS receiver on the ground in a known location (base station) • Acts as a static reference point • Transmits error correction messages to other GPS receivers in the local area (real-time) • Differential correction can be done on computer after GPS data are collected (post-processed)

  32. How accurate is GPS? • Recreational and mapping grade.........................10-15 m • C/A code • Autonomous • Recreational and mapping grade.............................1-5 m • C/A code • With differential correction • Submeter mapping grade.............................10 cm to 1 m • C/A code & carrier • With differential correction • Survey grade.............................................................1 cm • Dual frequency • Advanced survey methods

  33. Six Main Sources of GPS Error • Atmospheric effects • Multipath effects • Satellite geometry • Measurement noise • Ephemeris data • Satellite clock drift

  34. Things to Take Away • 6 major sources of error affect the accuracy of GPS positions • Atmospheric error  largest source • Previously  SA • Almanac and ephemeris data are different • Differential correction increases accuracy

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