StarFire (navigation system)
StarFire is a wide-area
differential GPSdeveloped by John Deere's NavCom and Precision Farming groups. StarFire broadcasts additional "correction information" over satellite L-bandfrequencies around the world, allowing a StarFire-equipped receiver to produce position measurements accurate to well under one metre, with typical accuracy over a 24-hour being under 4.5 cm. StarFire is similar to the FAA's differential GPS Wide Area Augmentation System(WAAS), but considerably more accurate due to a number of techniques that improve its receiver-end processing.
StarFire came about after a meeting in 1994 among
John Deereengineers who were attempting to chart a course for future developments. At the time, a number of smaller companies were attempting to introduce yield-mapping systems combining a GPS receiver with a grain counter, which produced maps of a field showing its yield. The engineers felt this was one of the most interesting developments in the industry, but the accuracy of GPS, then still using Selective Availability, was simply too low to produce a useful map. The various providers went bankrupt over the next few years.
In 1997, a team was formed to solve the problem of providing a more accurate GPS fix. Along with members of John Deere's engineering team, a small project at
Stanford Universityalso took part, along with engineers at the Jet Propulsion Laboratory. They decided to produce a dGPS system that differed fairly dramatically from similar systems like WAAS.
How StarFire Addresses GPS Inaccuracy
Inaccuracy in the GPS is primarily due to distortion from "billows" in the
ionosphere, which introduce propagation delays that makes the satellite appear farther away than it really is. GPS is often quoted as having 15 m accuracy, although the signal itself is good to about 3 m given current electronics. Of the 12 m of additional error, ionospheric distortion accounts for about 5 m. Another 3 to 4 m is accounted for by errors in the satellite ephemerisdata, which is used to calculate the positions of the GPS satellites, and by clock driftin the satellite's internal atomic clocks.
dGPS correct for these errors by comparing the position measured using GPS with a known highly-accurate ground reference, and then calculating the difference and broadcasting it to users. Some of these corrections apply to any location, the corrections to the clocks and ephemeris data for instance, but the billows cover only a certain portion of the sky so a correction measured at any one ground station is only really useful for receivers located nearby. To make the corrections accurate over a large area, one would need to deploy many ground reference stations and broadcast a considerable amount of data for finely divided locations. For instance, WAAS uses twenty-five stations in the continental US, developing a grid spaced 5x5 degrees.
StarFire instead uses an advanced receiver to correct for ionospheric effects internally. To do this, it captures the P(Y) signal that is broadcast on two frequencies, L1 and L2, and compares the effects of the ionosphere on the propagation time of the two. Using this information, the ionospheric effects can be calculated to a very high degree of accuracy, meaning the StarFire dGPS signal can ignore this correction. The second P(Y) signal is encrypted and cannot be used by civilian receivers directly, but StarFire doesn't use the data contained in the signal; it only compares the phase of the two signals instead. This is expensive in terms of electronics, requiring a second tuner and excellent signal stability to be useful, which is why the StarFire-like solution is not more widely used (at least when it was being created).
With the ionospheric correction handled internally, the StarFire dGPS signal is greatly reduced in the amount of information it needs to carry, which consists of a set of correction signals for the satellite data alone. Since these corrections are globally valid, and there are only 24 satellites in operation at any time, the total amount of information is quite limited. StarFire broadcasts this data at 300 baud, repeating once a second. The corrections are generally valid for about 20 minutes. In addition to ephemeris and clock corrections, the signal also contains information on the health of each satellite, offering quality-of-service data in near real-time, with about a 3 second delay in updating the signals from the ground station.
StarFire has developed through two versions. The first, retroactively known as SF1, offered 1-sigma accuracy of about 1 m. Its error was about 15 to 30 cm, meaning that while the displayed position (absolute accuracy) might be off by about 1 m, it could return you to within centimeters of a previously measured spot (relative accuracy). This was enough for the intended role, field surveying. This system was first offered in 1998, and since its replacement the SF1 signal is apparently now offered for free.
The newer system, SF2, was introduced in 2004. It dramatically improves accuracy, with a 1-sigma absolute accuracy of about 4.5 cm. In other words, StarFire will generally leave you within 5 cm of a particular geographical point, and will almost always be accurate to under 10 cm. The relative accuracy is likewise improved, to about 2.5 cm.
Even if the StarFire correction signal is lost for more than 20 minutes, the internal ionospheric corrections alone result in accuracy of about 3 m. StarFire receivers also receive WAAS signals, ignoring their ionospheric data and using their (less detailed) ephemeris and clock adjustment data to provide about 50 cm accuracy. In comparison, "normal" GPS receivers generally offer about 15 m accuracy, and ones using WAAS improve this to about 3 m.
When initially deployed, StarFire used seven reference stations in the continental US. The corrections generated at these stations are sent to two redundant processing stations (one co-located with a reference/monitor site), and then the resulting signal is uplinked from an east-coast US station. All of the stations are linked over the
internet, with dedicated ISDNlines and VSATlinks as backups. The resulting signals were broadcast from an Inmarsat III channel.
Additional StarFire networks were later set up in South America, Australia and Europe, each run from their own reference stations and sending data to their own satellites. As use of the system grew, the decision was made to link the various "local area" networks into a single global one. Today the StarFire network uses twenty-five stations worldwide, calculating and uplinking data from the US stations as before. It should be noted that the data collected at these stations is not location-dependent, in contrast to most dGPS, and the large number of sites is used primarily for redundancy.
John Deere also sells a
Real Time KinematicdGPS, StarFire RTK. RTK consists of a small tripod-mounted GPS receiver that uses StarFire signals to perform its own dGPS calculations relative to a point, normally the corner of a field. The unit then broadcasts these corrections over a radio link to the equipment-mounted receivers. RTK offers absolute accuracy of about 2 cm, and relative accuracy in the millimeters. This sort of accuracy is used for fully-automated equipment with autodrive systems.
* E-mail with NavCom
* [http://www.navcomtech.com/docs/StarFireSystem.pdf John Deere’s StarFire System: WADGPS for Precision Agriculture]
* [http://www.progressiveengineer.com/PEWebBackissues2005/PEWeb%2060%20Mar05-2/Deere.htm Nothing Runs Like a Precision Farming System]
Wikimedia Foundation. 2010.
Look at other dictionaries:
Compass navigation system — For navigation with a magnetic compass, see compass. Comparison of GPS, GLONASS, Galileo and Compass (medium earth orbit) satellite navigation system orbits with the International Space Station, Hubble Space Telescope and Iridium constellat … Wikipedia
Starfire — may refer to:In military usage: * F 94 Starfire, an American fighter aircraft * Starfire Optical Range, a United States Air Force research laboratoryIn comics: * Starfire (comics), a DC Comics superheroine, a member of the Teen Titans. * Starfire … Wikipedia
Navigation — This article is about determination of position and direction on or above the surface of the earth. For other uses, see Navigation (disambiguation). Table of geography, hydrography, and navigation, from the 1728 Cyclopaedia. Navigation is the… … Wikipedia
Satellite navigation — Geodesy Fundamentals Geodesy · … Wikipedia
Global Positioning System — GPS redirects here. For other uses, see GPS (disambiguation). Geodesy Fundamentals … Wikipedia
Global navigation satellite system — (GNSS) is the standard generic term for satellite navigation systems that provide autonomous geo spatial positioning with global coverage. A GNSS allows small electronic receivers to determine their location (longitude, latitude, and altitude) to … Wikipedia
Système Satellite Global de Navigation — Système de positionnement par satellites GNSS (Global Navigation Satellite System) est le nom général des systèmes de navigation satellitaires fournissant une couverture globale de géopositionnement à usage civil. Les GNSS utilisent les… … Wikipédia en Français
Multi-functional Satellite Augmentation System — (MSAS) is a Japanese SBAS (Satellite Based Augmentation System), i.e. a satellite navigation system which supports differential GPS (DGPS) designed to supplement the GPS system by reporting (then improving) on the reliability and accuracy of… … Wikipedia
Wide Area Augmentation System — FAA WAAS logo … Wikipédia en Français
Wide Area Augmentation System - WAAS — FAA WAAS logo … Wikipédia en Français