global positioning system - wikipedia, the free encyclopedia
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Global Positioning System - Wikipedia, the free encyclopedia
Global Positioning System
From Wikipedia, the free encyclopedia
(Redirected from GPS)
GPS satellite in orbit, image courtesy NASA
The Global Positioning System, usually called GPS, is the only fully-functional satellite
navigation system. A constellation of more than two dozen GPS satellites broadcasts precise
timing signals by radio to GPS receivers, allowing them to accurately determine their location
(longitude, latitude, and altitude) in any weather, day or night, anywhere on Earth.
GPS has become a vital global utility, indispensable for modern navigation on land, sea, and air
around the world, as well as an important tool for map-making and land surveying. GPS also
provides an extremely precise time reference, required for telecommunications and some scientific
research, including the study of earthquakes.
The United States Department of Defense developed the system, officially named NAVSTAR
GPS (Navigation Signal Timing and Ranging GPS), and launched the first experimental satellite
in 1978. The satellite constellation is managed by the 50th Space Wing. Although the cost of
maintaining the system is approximately US$400 million per year, including the replacement of
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aging satellites, GPS is available for free use in civilian applications as a public good.
In late 2005, the first in a series of next-generation GPS satellites was added to the constellation,
offering several new capabilities, including a second civilian GPS signal called L2C for enhanced
accuracy and reliability. In the coming years, additional next-generation satellites will increase
coverage of L2C and add a third and fourth civilian signal to the system, as well as advanced
military capabilities.
The Wide Area Augmentation System (WAAS), available since August 2000, increases the
accuracy of GPS signals to within 2 meters (6 ft) [1] for compatible receivers. GPS accuracy can
be improved further, to about 1 cm (half an inch) over short distances, using techniques such as
Differential GPS (DGPS).
Magellan GPS receiver in a marine application.
Over fifty GPS satellites such as this NAVSTAR have been launched since 1978.
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Contents
● 1 Applications ❍ 1.1 Military ❍ 1.2 Navigation ❍ 1.3 Location-based services ❍ 1.4 Location-based games ❍ 1.5 Aircraft passengers ❍ 1.6 Surveying ❍ 1.7 Agriculture ❍ 1.8 Geophysics and geology ❍ 1.9 Precise time reference
● 2 History ● 3 Technical description
❍ 3.1 Navigation signals ❍ 3.2 Calculating positions
● 4 Accuracy ❍ 4.1 Best case ❍ 4.2 Atmospheric effects ❍ 4.3 Multipath effects ❍ 4.4 Ephemeris and clock errors
● 5 Techniques to improve accuracy ● 6 Selective availability ● 7 Satellites
❍ 7.1 Frequencies used ● 8 Receivers ● 9 Time dilation
❍ 9.1 Awards ● 10 GPS tracking ● 11 GPS jamming ● 12 Other systems ● 13 See also ● 14 References ● 15 External links
Applications
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Military
GPS allows accurate targeting of various military weapons including cruise missiles and precision-
guided munitions, as well as improved command and control of forces through improved
locational awareness. The satellites also carry nuclear detonation detectors, which form a major
portion of the United States Nuclear Detonation Detection System. Civilian GPS receivers are
required to have limits on the velocities and altitudes at which they will report coordinates; this is
to prevent them from being used to create improvised missiles. [2]
Navigation
This taxi in Kyoto, equipped with GPS navigation, is an example of how GPS technology can be applied in routine activities.
GPS is used by people around the world as a navigation aid in cars, airplanes, and ships. Hand-
held GPS receivers can be used by mountain climbers and hikers. Glider pilots use the logged
signal to verify their arrival at turn points in competitions. Low cost GPS receivers are often
combined with PDAs, cell phones, car computers, or vehicle tracking systems. Examples of GPS-
based services are MapQuest Mobile and TomTom digital maps. The system can be used to
automate harvesters, mine trucks, and other vehicles. GPS equipment for the visually impaired is
available.
Location-based services
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GPS functionality can be used by emergency services and location-based services to locate mobile
phones. Assisted GPS is a GPS technology often used by the mobile phone because it reduces the
power requirements of the mobile phone and increases the accuracy of the location obtained. GPS
provides a location solution which is less dependent on the telecommunications network topology,
but more dependent on the mobile phone than methods using radiolocation. The ability to locate a
mobile phone to reasonable accuracy is mandated in the United States by E911 emergency
services legislation. The mobile phone location may also be used to provide location specific
information to the mobile phone, such as location specific advertising, or providing service
information specific to the phone user's geographic location.
Location-based games
GPS receivers come in a variety of formats, from devices integrated into cars, phones, and watches, to dedicated devices such those shown here from manufacturers Trimble, Garmin and
Leica (respectively, left to right).
The availability of hand-held GPS receivers for a cost of about $90 and up (as of March 2005) has
led to recreational applications including location-based games like the popular game Geocaching.
Geocaching involves using a hand-held GPS unit to travel to a specific longitude and latitude to
search for objects hidden by other geocachers. This popular activity often includes walking or
hiking to natural locations. Other location-based games are played controversially by two or more
teams on the streets of a city, but most of these are rather still in the stage of research prototypes
than a commercial success.
Aircraft passengers
Most airlines allow passenger use of GPS units on their flights, except during landing and take-off
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when other electronic devices are also restricted. Even though inexpensive consumer GPS units
have a minimal risk of interference, there is still a potential for interference. Because of this
possibility, a few airlines disallow use of hand-held receivers for safety reasons. However, other
airlines integrate aircraft tracking into the seat-back television entertainment system, available to
all passengers even during takeoff and landing.[3]
Even fixed systems may use GPS, in order to get precise time. This antenna is mounted on the roof of a hut containing a scientific experiment needing precise timing.
Surveying
More costly and precise receivers are used by land surveyors to locate boundaries, structures, and
survey markers, and for road construction. There is also a growing demand for Automatic Grade
Control systems that use GPS positions and 3D site plans to automatically control the blades and
buckets of construction equipment.
Agriculture
GPS is used for the guidance of tractors and other large agricultural machines via auto steer or a
visual aid displayed on a screen, which is extremely useful for controlled traffic and row crop
operations and when spraying. As well as guidance, GPS used in harvesters with yield monitors
can provide a yield map of the paddock being harvested.
Geophysics and geology
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High precision measurements of crustal strain can be made with GPS by finding the relative
displacement between GPS sites, one of which is assumed to be stationary. Multiple stations
situated around an actively deforming area (such as a volcano or fault zone) can be used to find
strain and site velocities relative to a stable reference site. These measurements can then be
inverted using the relationships between stress and strain to interpret the source and cause of the
deformation. For example, measurements of ground deformation around a volcano can be used to
interpret the source and cause—a dike, sill, or other body beneath the surface.
Precise time reference
Many systems that must be accurately synchronized use GPS as a source of accurate time. For
instance, the GPS can be used as a reference clock for time code generators or NTP clocks. Also,
when deploying sensors (for seismology or other monitoring application), GPS may be used to
provide each recording apparatus with a precise time source, so that the time of events may be
recorded accurately. Communications networks often rely on this precise timing to synchronize
RF generating equipment, network equipment, and multiplexers.
The atomic clocks on the satellites are set to "GPS time". GPS time is counted in days, hours,
minutes, and seconds, in the manner that is conventional for most time standards. However, GPS
time is not corrected to the rotation of the Earth, ignoring leap seconds and other corrections. GPS
time was set to read the same as Coordinated Universal Time (UTC) in 1980, but has since
diverged as leap seconds were added to UTC.
The GPS day is identified in the GPS signals using a week number along with a day-of-week
number. GPS week zero started at 00:00:00 UTC (00:00:19 TAI) on January 6, 1980. The week
number is transmitted in a ten-bit field, and so it wraps round every 1,024 weeks (7,168 days). The
transmitted week number returned to zero at 00:00:19 TAI on August 22, 1999 (23:59:47 UTC on
August 21, 1999). GPS receivers thus need to know the time to within 3,584 days in order to
correctly interpret the GPS time signal. A new field is being added to the GPS navigation message
that supplies the calendar year number in a sixteen-bit field, thus performing this disambiguation
for any receivers that know about the new field.
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The GPS navigation message also includes the difference between GPS time and UTC, which is
14 seconds as of 2006. Receivers subtract this offset from GPS time in order to display UTC time.
They may further adjust the UTC time adjust for a local time zone. New GPS units will initially
show the incorrect UTC time, or not attempt to show UTC time at all, after achieving a GPS lock
for the first time. However, this is usually corrected within 15 minutes, once the UTC offset
message is received for the first time. The GPS-UTC offset field is only eight bits, and so it wraps
round every 256 leap seconds. There is also a leap second warning bit, to help GPS receivers tick
UTC correctly through a leap second, but its use is troublesome because of misunderstandings
about its semantics.
History
The design of GPS is based partly on the similar ground-based radio navigation systems, such as
LORAN developed in the early 1940s, and used during World War II. Additional inspiration for
the GPS system came when the Soviet Union launched the first Sputnik in 1957. A team of U.S.
scientists led by Dr. Richard B. Kershner were monitoring Sputnik's radio transmissions. They
discovered that, because of the Doppler effect, the frequency of the signal being transmitted by
Sputnik was higher as the satellite approached, and lower as it continued away from them. They
realized that since they knew their exact location on the globe, they could pinpoint where the
satellite was along its orbit by measuring the Doppler distortion. The converse is also true: if the
satellite's position were known, they could identify their own position on Earth.
The first satellite navigation system, Transit, used by the United States Navy, was first
successfully tested in 1960. Using a constellation of five satellites, it could provide a navigational
fix approximately once per hour. In 1967, the U.S. Navy developed the Timation satellite which
proved the ability to place accurate clocks in space, a technology the GPS system relies upon. In
the 1970s, the ground-based Omega Navigation System, based on signal phase comparison,
became the first world-wide radio navigation system.
The first experimental Block-I GPS satellite was launched in February 1978.[4] The GPS satellites
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were initially manufactured by Rockwell International and are now manufactured by Lockheed
Martin.
In 1983, after Soviet interceptor aircraft shot down the civilian airliner KAL 007 in restricted
Soviet airspace, killing all 269 people on board, Ronald Reagan announced that the GPS system
would be made available for civilian uses once it was completed.
By 1985, ten more experimental Block-I satellites had been launched to validate the concept. The
first modern Block-II satellite was launched on February 14, 1989.
In 1992, the 2d Space Operations Squadron, which originally managed the system, was
inactivated and replaced by the 50th Space Wing.
The system achieved initial operational capability by December 1993[5] A complete constellation
of 24 satellites was in orbit by January 17, 1994.
In 1996, recognizing the importance of GPS to civilian users as well as military users, President
Bill Clinton issued a policy directive[6] declaring GPS to be a dual-use system and establishing an
Interagency GPS Executive Board to manage it as a national asset.
In 1998, Vice President Al Gore announced plans to upgrade GPS with two new civilian signals
for enhanced user accuracy and reliability, particularly with respect to aviation safety.
In 2004, President George W. Bush updated the national policy, replacing the board with the
National Space-Based Positioning, Navigation, and Timing Executive Committee.
The most recent launch was in September 2005. The oldest GPS satellite still in operation was
launched in February 1989.
Technical description
Navigation signals
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GPS broadcast signal
GPS satellites broadcast three different types of data in the primary navigation signals. The first is
the almanac which sends coarse time information with second precision along with status
information about the satellites. The second is the ephemeris, which contains orbital information
that allows the receiver to calculate the position of the satellite at any point in time. These bits of
data are folded into the 37,500 bit Navigation Message, or NM, which takes 12.5 minutes to send
at 50 Hz.
The satellites also broadcast two forms of accurate clock information, the Coarse Acquisition
code, or C/A, and the Precise code, or P-code. The former is normally used for most civilian
navigation. It consists of a 1,023 bit long pseudo-random code broadcast at 1.023 MHz, repeating
every millisecond. Each satellite sends a distinct C/A code, which allows them to be identified.
The P-code is a similar code broadcast at 10.23 MHz, but it repeats only once per week. In normal
operation, the so-called "anti-spoofing mode", the P code is first encrypted into the Y-code, or P
(Y), which can only be decrypted by units with a valid decryption key. All three signals, NM, C/A
and P(Y), are mixed together and sent on the primary radio channel, L1, at 1575.42 MHz. The P
(Y) signal is also broadcast alone on the L2 channel, 1227.60 MHz. Several additional frequencies
are used for unrelated purposes.
Calculating positions
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GPS allows receivers to accurately calculate their distance from the GPS satellites. The receivers
do this by measuring the time delay between when the satellite sent the signal and the local time
when the signal was received. This delay, multiplied by the speed of light, gives the distance to
that satellite. The receiver also calculates the position of the satellite based on information
periodically sent in the same signal. By comparing the two, position and range, the receiver can
discover its own location.
Pseudorange
To calculate its position, a receiver first needs to know the precise time. To do this, it uses an
internal crystal oscillator-based clock that is continually updated by the signals being sent in L1
from various satellites. At that point the receiver identifies the visible satellites by the distinct
pattern in their C/A codes. It then looks up the ephemeris data for each satellite, which was
captured from the NM and stored in memory. This data is used in a formula that calculates the
precise location of the satellites at that point in time.
Finally the receiver must calculate the time delay to each satellite. To do this, it produces an
identical C/A sequence from a known seed number. The time delay is calculated by increasingly
delaying the local signal and comparing it to the one received from the satellite; at some point the
two signals will match up, and that delay is the time needed for the signal to reach the receiver.
The delay is generally between 65 and 85 milliseconds. The distance to that satellite can then be
calculated directly, the so-called pseudorange.
The receiver now has two key pieces of information: an accurate estimate of the position of the
satellite, and an accurate measurement of the distance to that satellite. This tells the receiver that it
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lies on the surface of an imaginary sphere whose radius is that distance. To calculate the precise
position, at least four such measurements are taken simultaneously. This places the receiver at the
intersection of the four imaginary spheres. Since the C/A pattern repeats every millisecond, it can
only be used to place the user within 300 kilometers (180 mi). Thus the multiple measurements
are also needed to determine whether the receiver has lined up its internal C/A code properly, or is
"one off".
The calculation of the position of the satellite, and thus the time delay and range to it, all depend
on the accuracy of the local clock. The satellites themselves are equipped with extremely accurate
atomic clocks, but this is not economically feasible for a receiver. Instead, the system takes
redundant measurements to re-capture the correct clock information.
To understand how this works, consider a local clock that is off by .1 microseconds, or about 30
meters (100 ft) when converted to distance. When the position is calculated using this clock, the
range measurements to each of the satellites will read 30 meters too long. In this case the four
spheres will not overlap at a point, instead each sphere will intersect at a different point, resulting
in several potential positions about 30 meters apart. The receiver then uses a mathematical
technique to calculate the clock error that would produce this offset, in this case .1 microseconds,
adjusts the range measurements by this amount, and then updates the internal clock to make it
more accurate.
This technique can be applied with any four satellites. Commercial receivers therefore attempt to
"tune in" to as many satellites as possible, and repeatedly make this correction. In doing so, clock
errors can be reduced almost to zero. In practice, anywhere from six to ten measurements are
taken in order to round out errors, and civilian receivers generally have 10 to 12 channels in total.
Calculating a position with the P(Y) signal is generally similar in concept, assuming one can
decrypt it. The encryption is essentially a safety mechanism; if a signal can be successfully
decrypted, it is reasonable to assume it is a real signal being sent by a GPS satellite. In
comparison, the C/A signal can be generated fairly easily, allowing an unscrupulous user to send
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out their own fake signal, which would be difficult to distinguish from the original. Mathematical
techniques can be used here as well, making spoofing of the C/A signal a very difficult prospect
for any modern receiver equipped with some sort of RAIM system.
Accuracy
Best case
The position calculated by a GPS receiver relies on three accurate measurements: the current time,
the position of the satellite, and the time delay for the signal. Errors in the clock signal can be
reduced using the method above, meaning that the overall accuracy of the system is generally
based on the accuracy of the position and delay.
The measurement of the delay requires the receiver to "lock onto" the same sequence of bits being
sent from the satellite. This can be made relatively accurate by timing comparing the rising or
trailing edges of the bits. Modern electronics can lock the two signals to about 1% of a bit time, or
in this case about 1% of a microsecond. Since light travels at 299,792,458 m/s, this represents an
error of about 3 meters (10 ft), the minimum error possible given the timing of the C/A signal.
This can be improved by using the higher-speed P(Y) signal, assuming the same 1% accuracy in
locking the retrieved P-code to the internally generated version. In this case the same calculation
results in an accuracy of about 30 centimeters (1 ft). Since the P-code repeats at 10.23 MHz, it has
a "repeat range" of about 30 kilometers (20 mi). This explains the terminology; when using the P-
code, it was first necessary to calculate a coarse position with the C/A code in order to determine
how to line up the P-code with the internally generated copy.
However, several "real world" effects intrude and degrade the accuracy of the system. These are
outlined in the table below, with descriptions following. When all of these effects are added up,
GPS is typically accurate to about 15 meters (50 ft). These effects also overwhelm the P(Y) code's
added accuracy.
Sources of error
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Source Effect
Ionospheric effects ± 5 meter
Ephemeris errors ± 2.5 meter
Satellite clock errors ± 2 meter
Multipath distortion ± 1 meter
Tropospheric effects ± 0.5 meter
Numerical errors ± 1 meter or less
Atmospheric effects
One of the biggest problems for GPS accuracy is that changing atmospheric conditions change the
speed of the GPS signals unpredictably as they pass through the ionosphere. The effect is
minimized when the satellite is directly overhead and becomes greater toward the horizon, since
the satellite signals must travel through the greater "thickness" of the ionosphere as the angle
increases. Once the receiver's rough location is known, an internal mathematical model can be
used to estimate and correct for the error.
Because ionospheric delay affects the speed of radio waves differently based on their frequencies,
the second frequency band (L2) can be used to help eliminate this type of error. Some military and
expensive survey-grade civilian receivers can compare the difference between the P(Y) signal
carried in the L1 and L2 frequencies to measure atmospheric delay and apply precise corrections.
This correction can be applied even without decrypting the P(Y) signal, as long as the encryption
key is the same on both channels. In order to make this easier, the military is considering
broadcasting the C/A signal on L2 starting with the Block III-R satellites. This would allow a
direct comparison of the L1 and L2 signals using the same circuitry that already decodes the C/A
on L1.
The effects of the ionosphere are generally slow-moving and can easily be tracked. The effects for
any particular geographical area can be easily calculated by comparing the GPS-measured
position to a known surveyed location. This correction, say, "10 meters to the east" is also valid
for other receivers in the same general location. Several systems send this information over radio
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or other links to the receivers, allowing them to make better corrections that a comparison of L1
and L2 alone could.
The amount of humidity in the air also has a delaying effect on the signal, resulting in errors
similar to those generated in the ionosphere but located much closer to the ground in the
troposphere. The areas affected by these problems tend to be smaller in area and faster moving
than the billows in the ionosphere, making accurate correction for these effects more difficult.
Multipath effects
GPS signals can also be affected by multipath issues, where the radio signals reflect off
surrounding terrain; buildings, canyon walls, hard ground, etc. This delay in reaching the receiver
causes inaccuracy. A variety of receiver techniques, most notably narrow correlator spacing, have
been developed to mitigate multipath errors. For long delay multipath, the receiver itself can
recognize the wayward signal and discard it. To address shorter delay multipath from the signal
reflecting off the ground, specialized antennas may be used. This form of multipath is harder to
filter out since it is only slightly delayed as compared to the direct signal, causing effects almost
indistinguishable from routine fluctuations in atmospheric delay.
Multipath effects are much less severe in dynamic applications such as cars and planes. When the
GPS antenna is moving, the false solutions using reflected signals quickly fail to converge and
only the direct signals result in stable solutions.
Ephemeris and clock errors
The navigation message from a satellite is sent out only every 12.5 minutes. In reality, the data
contained in these messages tends to be "out of date" by an even larger amount. Consider the case
when a GPS satellite is boosted back into a proper orbit; for some time following the maneuver,
the receiver’s calculation of the satellite's position will be incorrect until it receives another
ephemeris update. Additionally, the amount of accuracy sent in the ephemeris is limited by the
bandwidth; using the data from the satellites alone limits its accuracy.
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Further, while it is true that the onboard clocks are extremely accurate, they do suffer from clock
drift. This problem tends to be very small, but may add up to 2 meters (6 ft) of inaccuracy.
These sorts of errors are even more "stable" than ionospheric problems and tend to change on the
order of days or weeks, as opposed to minutes. This makes correcting for these errors fairly simple
by sending out a more accurate almanac on a separate channel.
Techniques to improve accuracy
The accuracy of GPS can be improved several ways:
● Differential GPS (DGPS) can improve the normal GPS accuracy of 4-20 meters (13-65 ft)
to 1-3 meters (3-10 ft).[7] DGPS uses a network of stationary GPS receivers to calculate the difference between their actual known position and the position as calculated by their received GPS signal. The "difference" is broadcast as a local FM signal, allowing many civilian GPS receivers to "fix" the signal for greatly improved accuracy. The US Coast Guard maintains a similar system on marine longwave radio near ports and major waterways, supplemented by additional sites in Canada.
● The Wide Area Augmentation System (WAAS). This system uses a series of ground reference stations to calculate GPS correction messages, which are uploaded to a series of additional satellites in geosynchronous orbit for transmission to GPS receivers, including information on ionospheric delays and individual satellite clock drift. Although only a few WAAS satellites are currently available as of 2004, it is hoped that eventually WAAS will provide sufficient reliability and accuracy that it can be used for critical applications such as GPS-based instrument approaches in aviation (landing an airplane in conditions of little or no visibility). The current WAAS only works for North America (where the reference stations are located), and because of the satellite location, the system is only generally usable in the eastern and western coastal regions. However, variants of the WAAS are being developed in Europe (EGNOS, the European Geostationary Navigation Overlay Service) and Japan (MSAS, the Multi-Functional Satellite Augmentation System), which are virtually identical to WAAS.
● A Local Area Augmentation System (LAAS). This is similar to WAAS, in that similar correction data are used. But in this case, the correction data are transmitted from a local source, typically at an airport or another location where accurate positioning is needed. These correction data are typically useful for only about a thirty to fifty kilometer (20-50 mi) radius around the transmitter.
● Exploitation of DGPS for Guidance Enhancement (EDGE) is an effort to integrate DGPS into precision guided munitions such as the Joint Direct Attack Munition (JDAM).
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● A Carrier-Phase Enhancement (CPGPS). This technique utilizes the 1.575 GHz L1 carrier wave to act as a sort of additional clock signal, resolving ambiguity caused by variations in the location of the pulse transition (logic 1-0 or 0-1) of the C/A PRN signal. The problem arises because the transition from 0-1 or 1-0 on the C/A signal is not instantaneous, it takes a non-zero amount of time, and thus the correlation (satellite-receiver sequence matching) operation is imperfect. A successful correlation could be defined in a number of various places along the rising/falling edge of the pulse, which imparts timing errors. CPGPS solves this problem by using the L1 carrier, which has a period 1/1000 that of the C/A bit width, to define the transition point instead. The phase difference error in the normal GPS amounts to a 2-3 meter (6-10 ft) ambiguity. CPGPS working to within 1% of perfect transition matching can achieve 3 mm ambiguity; in reality, CPGPS coupled with DGPS normally realizes 20-30 centimeter (8-12 in) accuracy.
● Wide Area GPS Enhancement (WAGE) is an attempt to improve GPS accuracy by providing more accurate satellite clock and ephemeris (orbital) data to specially-equipped receivers.
● Relative Kinematic Positioning (RKP) is another approach for a precise GPS-based positioning system. In this approach, accurate determination of range signal can be resolved to an accuracy of less than 10 centimeters (4 in). This is done by resolving the number of cycles in which the signal is transmitted and received by the receiver. This can be accomplished by using a combination of differential GPS (DGPS) correction data, transmitting GPS signal phase information and ambiguity resolution techniques via statistical tests—possibly with processing in real-time (real-time kinematic positioning, RTK).
● Many automobiles that use the GPS combine the GPS unit with a gyroscope and speedometer pickup, allowing the computer to maintain a continuous navigation solution by dead reckoning when buildings, terrain, or tunnels block the satellite signals. This is similar in principle to the combination of GPS and inertial navigation used in ships and aircraft, but less accurate and less expensive because it only fills in for short periods.
Selective availability
When it was first deployed, GPS included a feature called Selective Availability (SA) that
introduced intentional errors of up to a hundred meters (300 ft) into the publicly available
navigation signals, making it difficult to use for guiding long range missiles to precise targets.
Additional accuracy was available in the signal, but in an encrypted form that was only available
to the United States military, its allies and a few others, mostly government users.
SA typically added signal errors of up to about 10 meters (30 ft) horizontally and 30 meters (100
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ft) vertically. The inaccuracy of the civilian signal was deliberately encoded so as not to change
very quickly, for instance the entire eastern U.S. area might read 30 m off, but 30 m off
everywhere and in the same direction. In order to improve the usefulness of GPS for civilian
navigation, Differential GPS was used by many civilian GPS receivers to greatly improve
accuracy.
During the Gulf War, the shortage of military GPS units and the wide availability of civilian ones
among personnel resulted in a decision to disable Selective Availability. This was, perhaps, ironic,
as SA had been introduced specifically for these situations, allowing friendly troops to use the
signal for accurate navigation, while at the same time denying it to the enemy. But since SA was
also denying the same accuracy to thousands of friendly troops, turning it off presented a clear
benefit.
In the 1990s, the FAA started pressuring the military to turn off SA permanently. This would save
the FAA millions of dollars every year in maintenance of their own radio navigation systems. The
military resisted for most of the 1990s, but SA was eventually turned off[8] in 2000 following an
announcement by U.S. President Bill Clinton, allowing users access to an undegraded L1 signal.
The US military has developed the ability to locally deny GPS (and other navigation services) to
hostile forces in a specific area of crisis without affecting the rest of the world or its own military
systems. Such Navigation Warfare uses techniques such as local jamming to replace the blunt,
world-wide degradation of civilian GPS service that SA represented.
Military (and selected civilian) users still enjoy some technical advantages which can give quicker
satellite lock and increased accuracy. The increased accuracy comes mostly from being able to use
both the L1 and L2 frequencies and thus better compensate for the varying signal delay in the
ionosphere.
Satellites
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GPS satellite on test rack
As of August 2006 the GPS system used a satellite constellation of 29 active Block II/IIA/IIR/IIR-
M satellites (for the global coverage 24 is enough) in intermediate circular orbits. The
constellation includes three spare satellites in orbit, in case of any failure. Each satellite circles the
Earth twice each day at an altitude of 20,200 kilometers (12,600 miles). The orbits are aligned so
at least four satellites are always within line of sight from almost any place on Earth. [9] There are
four active satellites in each of six orbital planes. Each orbit is inclined 55 degrees from the
equatorial plane, and the right ascension of the ascending nodes is separated by sixty degrees. [10]
The flight paths of the satellites are measured by five monitor stations around the world (Hawaii,
Kwajalein, Ascension Island, Diego Garcia, Colorado Springs). The master control station, at
Schriever Air Force Base, processes their combined observations and sends updates to the
satellites through the stations at Ascension Island, Diego Garcia, and Kwajalein. The updates
synchronize the atomic clocks on board each satellite to within one microsecond, and also adjust
the ephemeris of the satellites' internal orbital model to match the observations of the satellites
from the ground. [11]
Frequencies used
Several frequencies make up the GPS electromagnetic spectrum:
● L1 (1575.42 MHz):Carries a publicly usable coarse-acquisition (C/A) code as well as an encrypted precision P(Y) code.
● L2 (1227.60 MHz):Usually carries only the P(Y) code, but will also carry a second C/A code on the Block III-R satellites.
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● L3 (1381.05 MHz):Carries the signal for the GPS constellation's alternative role of detecting missile/rocket launches (supplementing Defense Support Program satellites), nuclear detonations, and other high-energy infrared events.
Two new signals are also being studied:
● L4 (1841.40 MHz):Being studied for additional ionospheric correction.
● L5 (1176.45 MHz):Proposed for use as a civilian safety-of-life (SoL) signal. This frequency falls into an internationally protected range for aeronautical navigation, promising little or no interference under all circumstances. The first Block IIF satellite that would provide this signal is set to be launched in 2008.
A modern SiRF Star III chip based 20-channel GPS receiver with WAAS/EGNOS support.
Receivers
GPS receivers vary widely in accuracy because of the expense of adding more radio receivers
needed to tune in more satellites. For instance, early consumer-grade receivers typically included
six to eight receivers for the L1 C/A signal. As the computer industry has improved the state of the
art in chipmaking, the cost of implementing these receivers has fallen dramatically, and even low-
cost hand held receivers typically have twelve receivers today. More expensive units, known as
"dual-frequency receivers", also tune in the L2 signals in order to correct for ionospheric delays.
Another major factor in the accuracy of a GPS fix is the amount of processing applied to the
received signals. This is a function of the performance of the electronics and the required battery
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life. These factors have also been dramatically affected by improved chip making, allowing even
low cost modern receivers to outperform much more expensive earlier models.
GPS receivers may include an input for differential corrections, using the RTCM SC-104 format.
This is typically in the form of a RS-232 port at 4,800 bps speed. Data is actually sent at a much
lower rate, which limits the accuracy of the signal sent using RTCM. Receivers with internal
DGPS receivers can outperform those using external RTCM data. The cost of implementing these
receivers is also falling dramatically, and even low-cost units are commonly including WAAS
receivers today.
Many GPS receivers can relay position data to a PC or other device using the NMEA 0183
protocol. NMEA 2000[12] is a newer and less widely adopted protocol. Both are proprietary and
are controlled on a for-profit basis by the US-based National Marine Electronics Association.
References to the NMEA protocols have been compiled from public records, allowing open
source tools like gpsd to read the protocol without violating intellectual property laws. Other
proprietary protocols exist as well, such as the SiRF protocol. Receivers can interface with
external devices via a number of means, such as a serial connection, a USB connection or even a
Bluetooth a wireless connection.
Time dilation
According to Einstein's theory of relativity, because of their constant movement with respect to
the Earth's reference frame the clocks on the satellites are affected by both special and general
relativity. According to the same theory, observing from the Earth's reference frame, satellite
clocks are perceived as running at a slightly faster rate than clocks on the Earth's surface. This
amounts to a discrepancy of around 38 microseconds per day, when observed from the Earth. To
account for this, the frequency standard on-board the satellites runs slightly slower than its desired
speed on Earth, at 10.22999999543 MHz instead of 10.23 MHz—a difference of 0.00457 Hz.[13]
This offset is claimed by relativity physicists to be a practical demonstration of the theory of
relativity in a real-world system; they claim it to be exactly what has been predicted by the theory;
however, even if true, this holds only within the limits of accuracy of measurements as affected by
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environmental effects.
Neil Ashby presented a controversial account of how these relativistic corrections are applied, and
their orders of magnitude, in Physics Today (May 2002).[14] Note that Einstein's relativity is
considered a mere correction to the Newtonian GPS theory. Namely, the relativistic corrections
cancel out even in high-accuracy (millimetre) GPS positioning, which shows that they are an
unnecessary mathematical complication altogether.
Thus in his book GPS Satellite Surveying, Alfred Leick writes (p.170): "In relative (mm)
positioning, most of the relativistic effects cancel or become negligible."[15] This is because the
relativity-predicted values, if real, would amount to less than one half of the normal environmental
(insurmountable) geophysical noise. Therefore, geometrical differencing in precise positioning
cancels out most of the relativistic effects; the GPS system can perform equally superb without SR
or GR theories.
Awards
Two GPS developers have received the National Academy of Engineering Charles Stark Draper
prize year 2003:
● Ivan Getting, emeritus president of The Aerospace Corporation and engineer at the Massachusetts Institute of Technology, established the basis for GPS, improving on the World War II land-based radio system called LORAN (Long-range Radio Aid to Navigation).
● Bradford Parkinson, teacher of aeronautics and astronautics at Stanford University, developed the system.
One GPS developer, Roger L. Easton, received the National Medal of Technology on February
13, 2006 at the White House.[16]
On February 10, 1993, the National Aeronautic Association selected the Global Positioning
System Team as winners of the 1992 Robert J. Collier Trophy, the most prestigious aviation
award in the United States. This team consists of researchers from the Naval Research Laboratory,
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the U.S. Air Force, the Aerospace Corporation, Rockwell International Corporation, and IBM
Federal Systems Company. The citation accompanying the presentation of the trophy honors the
GPS Team "for the most significant development for safe and efficient navigation and
surveillance of air and spacecraft since the introduction of radio navigation 50 years ago."
GPS tracking
GPS Navigation System using TomTom software
A GPS tracking system uses GPS to determine the location of a vehicle, person, or pet and to
record the position at regular intervals in order to create a track file or log of activities. The
recorded data can be stored within the tracking unit, or it may be transmitted to a central location,
or Internet-connected computer, using a cellular modem, 2-way radio, or satellite. This allows the
data to be reported in real-time, using either web browser based tools or customized software.
GPS jamming
Further information: Selective Availability / Anti-Spoofing Module
Jamming of any radio navigation system, including satellite based navigation, is possible. The U.
S. Air Force conducted GPS jamming exercises in 2003 and they also have GPS anti-spoofing
capabilities. In 2002, a detailed description of how to build a short range GPS L1 C/A jammer was
published in Phrack issue 60[17] by an anonymous author. There has also been at least one well-
documented case of unintentional jamming, tracing back to a malfunctioning TV antenna
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preamplifier.[18] If stronger signals were generated intentionally, they could potentially interfere
with aviation GPS receivers within line of sight. According to John Ruley, of AVweb, "IFR pilots
should have a fallback plan in case of a GPS malfunction".[19] Receiver Autonomous Integrity
Monitoring (RAIM), a feature of some aviation and marine receivers, is designed to provide a
warning to the user if jamming or another problem is detected. GPS signals can also be interfered
with by natural geomagnetic storms, predominantly at high latitudes.[20]
GPS jammers the size of a cigarette box are allegedly available from Russia; their effectiveness is
in question following their use in the Iraq War. The U.S. government believes that such jammers
were also used occasionally during the 2001 war in Afghanistan. Some officials believe that
jammers could be used to attract the precision-guided munitions towards non-combatant
infrastructure; other officials believe that the jammers are completely ineffective. In either case,
the jammers may be attractive targets for anti-radiation missiles. Low power jammers would have
limited military usefulness and high power jammers would be easy to locate and destroy. During
the Iraq War, the U.S. military claimed to destroy a GPS jammer with a GPS-guided bomb. [21]
Other systems
Russia operates an independent system called GLONASS (GLObal NAvigation Satellite System),
although with only twelve active satellites as of 2004, the system is of limited usefulness.
Availability in Russia, Northern Europe and Canada is above 90%. Meaning that at least 4
satelites are visible 90% of time, which is not bad considering that GLONASS operate only 12 of
24 required satelites. There are plans to restore GLONASS to full operation by 2008 with India's
help. The European Union is developing Galileo as an alternative to USA owned operated GPS
system. The People's Republic of China, Israel, India, Morocco, Saudi Arabia and South Korea
joined the EU in this project. It is planned to be in operation by 2010.
See also
Find more information on Global Positioning System by searching Wikipedia's sister projects:
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Dictionary definitions from Wiktionary
Textbooks from Wikibooks
Quotations from Wikiquote
Source texts from Wikisource
Images and media from Commons
News stories from Wikinews
● Wikipedia Geographical coordinates project - adding geographic coordinates to WikiPedia articles.
● Automotive navigation system ● Degree Confluence Project Use GPS to visit integral degrees of latitude and longitude. ● Geodashing, an outdoor sport using waypoints. ● Geocaching, an outdoor sport in which participants find hidden items at posted co-
ordinates. ● Category:Navigation system companies. ● WikiGPS, Wikimedia proposed project. ● World Geodetic System - WGS 84 datum is commonly used to represent GPS coordinates ● The American Practical Navigator - Satellite navigation, Chapter 11
References
1. ^ Federal Aviation Administration. FAA WAAS fact-sheet. EGNOS, the European equivalent, went on-line in 2005. Accessed May 14, 2006
2. ^ Arms Control Association. Missile Technology Control Regime. Accessed May 17, 2006.
3. ^ Joe Mehaffey. Is it Safe to use a handheld GPS Receiver on a Commercial Aircraft?. Accessed May 15, 2006.
4. ^ Hydrographic Journal. Developments in Global Navigation Satellite Systems. April 2002. Accessed May 14, 2006.
5. ^ United States Department of Defense. Announcement of Initial Operational Capability. December 8, 1993.
6. ^ National Archives and Records Administration. U.S. GLOBAL POSITIONING SYSTEM POLICY. March 29, 1996.
7. ^ Federal Highway Administration. Nationwide DGPS Program Fact Sheet. Accessed May
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14, 2006 8. ^ Office of Science and Technology Policy. Presidential statement to stop degrading GPS.
May 1, 2000. 9. ^ HowStuffWorks. How GPS Receivers Work. Accessed May 14, 2006.
10. ^ Dana, Peter H. GPS Orbital Planes. August 8, 1996. 11. ^ USNO. NAVSTAR Global Positioning System. Accessed May 14, 2006. 12. ^ NMEA NMEA 2000 13. ^ Rizos, Chris. University of New South Wales. GPS Satellite Signals. 1999. 14. ^ Physics Today. Relativity and GPS. May 2002. 15. ^ A Leick, GPS Satellite Surveying, Wiley & Sons, 2003. ISBN 0471059307. 16. ^ United States Naval Research Laboratory. National Medal of Technology for GPS.
November 21, 2005 17. ^ Phrack. Issue 0x3c (60), article 13. December 28, 2002. 18. ^ GPS World. The hunt for an unintentional GPS jammer. January 1, 2003. 19. ^ Ruley, John. AVweb. GPS jamming. February 12, 2003. 20. ^ Space Environment Center. SEC Navigation Systems GPS Page. August 26, 1996. 21. ^ American Forces Press Service. CENTCOM charts progress. March 25, 2003.
External links
● Current GPS constellation, updated daily ● Peter H. Dana: Global Positioning System Overview - Large amount of technical
information and discussion. ● GPS SPS Signal Specification, 2nd Edition - The official (civilian) signal specification. ● Satellite Navigation: GPS & Galileo (PDF) — 16-page paper about the history and
working of GPS, touching on the upcoming Galileo ● History of GPS, including information about each satellite's configuration and launch. ● U.S. Army Corps of Engineers manual: NAVSTAR HTML and PDF (22.6 MB, 328 pages) ● The Global Positioning System: Challenges in Bringing GPS to Mainstream Consumers
Technical Article by Kanwar Chadha, BSEE (1998) ● USCG Navigation Center, Status of the GPS constellation, government policy, and links to
other references. Also includes satellite almanac data. ● National Space-Based PNT Executive Committee - Established in 2004 to oversee
management of GPS and GPS augmentations at a national level. ❍ PNT Selective Availability Announcements
● The GPS Joint Program Office (GPS JPO) - Responsible for designing and acquiring the system on behalf of the US Government.
● FAA GPS faq ● GPS Weapon Guidance Techniques
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● University of New Brunswick, In Simple Terms, How Does GPS Work? ● u-blox GPS Tutorial (PDF) — Tutorial designed to introduce you to the principles behind
GPS ● Trimble's Online GPS Tutorial — excellent introduction for newbies ● RAND history of the GPS system (PDF) ● GPS Anti-Jam Protection Techniques
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