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Military Tracking Applications

GPS allows accurate targeting of various military weapons including cruise missiles and precision-guided munitions. To help prevent GPS guidance from being used in enemy or improvised weaponry, the US Government controls the export of civilian receivers. A US-based manufacturer cannot generally export a receiver unless the receiver contains limits restricting it from functioning when it is simultaneously (1) at an altitude above 18 kilometers (60,000ft) and (2) traveling at over 515 m/s (1,000 knots).

The GPS satellites also carry nuclear detonation detectors, which form a major portion of the United States Nuclear Detonation Detection System.

Driver GPS Navigation

Automobiles can be equipped with GPS receivers at the factory or as after-market equipment. Units often display moving maps and information about location, speed, direction, and nearby streets and landmarks.

Aircraft navigation systems usually display a "moving map" and are often connected to the autopilot for en-route navigation. Cockpit-mounted GPS receivers and glass cockpits are appearing in general aviation aircraft of all sizes, using technology such as WAAS or LAAS to increase accuracy. Many of these systems may be certified for instrument flight rules navigation and some can also be used for final approach and landing operations. Glider pilots use GNSS Flight Recorders to log GPS data verifying their arrival at turn points in gliding competitions. Flight computers installed in many gliders also use GPS to compute wind speed aloft, glide paths to way points such as alternate airports or mountain passes, and to aid en route decision making for cross-country soaring.

Boats and ships can use GPS to navigate all of the world's lakes, seas and oceans. Maritime GPS units include functions useful on water, such as "man overboard" (MOB) functions that allow instantly marking the location where a person has fallen overboard, which simplifies rescue efforts. GPS may be connected to the ships self-steering gear and Chart plotters using the NMEA 0183 interface. GPS can also improve the security of shipping traffic by enabling AIS.

Heavy Equipment can use GPS in construction, mining, and precision agriculture. The blades and buckets of construction equipment are controlled automatically in GPS-based machine guidance systems. Agricultural equipment may use GPS to steer automatically or as a visual aid displayed on a screen for the driver. This is very useful for controlled traffic, row crop operations, and when spraying. Harvesters with yield monitors can also use GPS to create a yield map of the paddock being harvested.

Bicyclists often use GPS in racing and touring. GPS navigation allows cyclists to plot their course in advance and follow this course, which may include quieter, narrower streets, without having to stop frequently to refer to separate maps. Some GPS receivers are specifically adapted for cycling with special mounts and housings.

Hikers, climbers, and even ordinary pedestrians in urban or rural environments can use GPS to determine their position with or without reference to separate maps. In isolated areas, the ability of GPS to provide a precise position can greatly enhance the chances of rescue when climbers or hikers are disabled or lost (if they have a means of communication with rescue workers).

GPS equipment for the visually impaired is also available.

Surveying and Mapping

Survey-Grade GPS receivers can be used to position survey markers.
A modern SiRF Star III chip based 20-channel GPS receiver with WAAS/EGNOS support.
Mapping and geographic information systems (GIS) - Most mapping grade GPS receivers use the carrier wave data from only the L1 frequency, but have a precise crystal oscillator that reduces errors related to receiver clock jitter. This allows positioning errors on the order of one meter or less in real-time with a differential GPS signal received using a separate radio receiver. By storing the carrier phase measurements and differentially post-processing the data, positioning errors on the order of 10 centimeters are possible with these receivers.

Geophysics and geology - High precision measurements of crustal strain can be made with differential GPS by finding the relative displacement between GPS sensors. Multiple stations situated around an actively deforming area (such as a volcano or fault zone) can be used to find strain and ground movement. These measurements can then be used to interpret the cause of the deformation, for example, a dike or sill beneath the surface of an active volcano.

Archeology - As archeologists excavate a site, they generally make a three-dimensional map of the site and detailing where each artifact is found.

Other Uses of GPS Technology

Precise Time Reference - Many systems that must be accurately synchronized use GPS as a source of accurate time. GPS can be used as a reference clock for time code generators or NTP clocks. Sensors for seismology or other monitoring applications can use GPS as a precise time source so events may be timed accurately. TDMA communications networks often rely on this precise timing to synchronize RF generating equipment, network equipment, and multiplexers.

Mobile Satellite Communications - Satellite communications systems use a directional antenna (usually a "dish") pointed at a satellite. The antenna on a moving ship or train, for example, must be pointed based on its current location. Modern antenna controllers usually incorporate a GPS receiver to provide this information.

Emergency and Location - based services - GPS functionality can be used by emergency services to locate cell phones. The ability to locate a mobile phone is required in the United States by E911 emergency services legislation. However, as of September 2006, such a system is not in place in all parts of the country. GPS is less dependent on the telecommunications network topology than radiolocation for compatible phones. Assisted GPS reduces the power requirements of the mobile phone and increases the accuracy of the location. A phone's geographic location may also be used to provide location-based services including advertising or other location-specific information.

Location - based games - The availability of hand-held GPS receivers has led to games such as Geocaching, which 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. Geocaching is an outdoor sport using way points.

Aircraft Passengers - Most airlines allow passenger use of GPS units on their flights, except during landing and take-off when other electronic devices are also restricted. Even though consumer GPS receivers have a minimal risk of interference, a few airlines disallow use of hand-held receivers during flight. Other airlines integrate aircraft tracking into the seat-back television entertainment system that is available to all passengers even during take-off and landing.

Heading Information - Even though it was not designed for this purpose, the GPS system can be used to determine heading information. A "GPS compass" uses a pair of antennas separated by about 50 cm to detect the phase difference in the carrier signal from a particular GPS satellite. Given the positions of the satellite, the position of the antenna, and the phase difference, the orientation of the two antennas can be computed. More expensive GPS compass systems use three antennas in a triangle to get three separate readings with respect to each satellite. A GPS compass is not subject to magnetic declination as a magnetic compass is, and doesn't need to be reset periodically like a gyrocompass. It is, however, subject to multi path effects.

GPS tracking systems use GPS to determine the location of a vehicle, person, or pet and to record the position at regular intervals in order to create a log of movements. The data can be stored inside the unit or sent to a remote computer by radio or cellular modem. Some systems allow the location to be viewed in real-time on the Internet with a web-browser.

Weather Prediction Improvements - Measurement of atmospheric bending of GPS satellite signals by specialized GPS receivers in orbital satellites can be used to determine atmospheric conditions such as air density, temperature, moisture and electron density. Such information from a set of six micro-satellites called the Constellation of Observing System for Meteorology, Ionosphere and Climate COSMIC was launched in April 2006 and has been proven to improve the accuracy of weather prediction models.

Photograph Annotation - Combining GPS position data with photographs taken with a (typically digital) camera allows one to lookup the locations where the photographs were taken in a gazetteer and automatically annotate the photographs with the name of the location they depict. The GPS device can be integrated into the camera or the timestamp of a picture's metadata can be combined with a GPS track log.

Skydiving - Most commercial drop zones use a GPS to aid the pilot to "spot" the plane to the correct position relative to the drop zone that will allow all skydivers on the load to be able to fly their canopies back to the landing area. The "spot" takes into account the number of groups exiting the plane and the upper winds. In areas where skydiving through clouds is permitted, the GPS can be the sole visual indicator when spotting in overcast conditions. This is referred to as a "GPS Spot".