Positioning system
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A positioning system is a mechanism for determining the location of an object in space. Technologies for this task exist ranging from worldwide coverage with meter accuracy to workspace coverage with sub-millimetre accuracy.
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[edit] Interplanetary systems
Interplanetary-radio communication system not only communicate with spacecraft, but are also used to determine their position. This can be done either using a transponder on-board a spacecraft that echoes a radio signal back, or using radar. Orientation information can be obtained using star trackers.
[edit] Global systems
Global navigation satellite systems (GNSS) allow specialized radio receivers to determine their 3-D space position, as well as time, with an accuracy of 2–20 metres or tens of nanoseconds. Currently deployed systems use microwave signals that can only be received reliably outdoors and that cover most of Earth's surface, as well as near-Earth space.
The existing and planned systems are:
- Global Positioning System – US military system, fully operational since 1995
- GLONASS – a partially completed Russian military system
- Galileo – a planned European civilian system
[edit] Regional systems
Networks of land-based positioning transmitter allow specialized radio receivers to determine their 2-D position on the surface of the Earth. They are generally less accurate than GNSS because the propagation of their signals is not entirely restricted to line-of-sight, and they have only regional coverage. However, they remain useful for special purposes and as a backup as some of their signals are more reliably to receive, including underground and in indoor environments, and receivers can be built that consume very low battery power.
Examples of existing systems include
[edit] Site-wide systems
Indoor positioning systems are optimized for use within individual rooms, buildings, or construction sites. They typically offer centimetre-accuracy. Some provide 6-D location and orientation information.
Examples of existing systems include
[edit] Workspace systems
These are designed to cover only a restricted workspace, typically a few cubic meters, but offer accuracy in the millimetre-range or better. They typically provide 6-D position and orientation. Example applications include virtual reality environments, alignment tools for computer-assisted surgery or radiology, and motion capture.
