Inertial navigation: Difference between revisions
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{{ | '''Inertial navigation''' is a technique of navigation that does not depend on external references such as compasses, celestial navigation|stars, gravity or GPS, but computes the present position by sensing the movement of the navigating platform from a precisely known starting point in space. The general approach is to use multiple gyroscopes as references for the axes of position, as well as for error correction, using accelerometers to sense the motion. | ||
'''Inertial navigation''' is a technique of | |||
There are two major types of inertial navigation sensors, gimballed, where the sensors can move, and strapdown, where they are bonded to the moving vehicle. | There are two major types of inertial navigation sensors, gimballed, where the sensors can move, and strapdown, where they are bonded to the moving vehicle. | ||
The method is exceptionally important for | The method is exceptionally important for precision-guided munitions, space vehicles, and military ships, submarines and aircraft, because it | ||
:*Does not require external navigation infrastructure | :*Does not require external navigation infrastructure | ||
:*Is resistant to | :*Is resistant to electronic warfare | ||
Inertial navigation is well-established technique; it is not to be confused with the concept of | Inertial navigation is well-established technique; it is not to be confused with the concept of inertial propulsion developed within the Russian space research program<!-- and qualified as pseudoscience by some authors.!-->. | ||
==Modes of operation== | ==Modes of operation== | ||
*Space stable | *Space stable | ||
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*Strapdown | *Strapdown | ||
In practice, inertial information is combined with other sources, such as | In practice, inertial information is combined with other sources, such as GPS satellite. | ||
==Enabling technologies== | ==Enabling technologies== | ||
Essential to inertial navigation are gyroscopes, accelerometers, and computers, as well as the mathematics of inertial position comutation. | Essential to inertial navigation are gyroscopes, accelerometers, and computers, as well as the mathematics of inertial position comutation. | ||
===Gyroscopes in inertial navigation=== | ===Gyroscopes in inertial navigation=== | ||
Gyroscopes, first used as non-magnetic compasses and as true vertical indicators in aviation, are the fundamental enabling technology. Inertial navigation greatly benefited when gyroscope technology moved beyond mechanical to optical techniques, which do not require moving parts and can be much smaller. | |||
Gyroscope-generated information includes: | Gyroscope-generated information includes: | ||
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*two degree of freedom gyro | *two degree of freedom gyro | ||
===Mathematics=== | ===Mathematics=== | ||
Inertial navigation is referenced to a | Inertial navigation is referenced to a geodesy|geodetic coordinate system. | ||
==Naval applications== | ==Naval applications== | ||
Compass#Gyrocompasses|Gyrocompasses were precursors of full inertial navigation. | |||
A first major implementation was the Ship Inertial Navigation System aboard the first U.S. | A first major implementation was the Ship Inertial Navigation System aboard the first U.S. ballistic missile submarines, which needed absolutely precise position information for accurate missile launching, but whose operational security depended on not exposing themselves for star sights, radio navigation, etc. While the submarine systems have continued to improve, and intertial navigation became common on surface warships, the United States Navy became concerned that it had multiple systems (i.e., AN-|AN/WSN-5 aboard surface combatants, the AN-|AN/WSN-3 aboard submarines and the AN-|AN/WSN-1 aboard aircraft carriers) where one would do, and that much less expensive commercial-off-the-shelf components were available. The AN-|AN/WSN-7 Ring Laser Gyro Navigation System, will replace all three, which are 15-20 years old and for which it is increasingly difficult to obtain spare parts. <ref>{{citation | ||
| url = https://acquisition.navy.mil/rda/home/acquisition_one_source/program_assistance_and_tools/best_practices_and_lessons_learned/acquiring_a_common_ndi_ship_submarine_inertial_navigation_system | | url = https://acquisition.navy.mil/rda/home/acquisition_one_source/program_assistance_and_tools/best_practices_and_lessons_learned/acquiring_a_common_ndi_ship_submarine_inertial_navigation_system | ||
| title = Acquiring a Common NDI Ship/Submarine Inertial Navigation System | | title = Acquiring a Common NDI Ship/Submarine Inertial Navigation System | ||
| publisher = Naval Sea Systems Command, | | publisher = Naval Sea Systems Command, United States Navy | ||
| author = Ring Laser Gyro Navigator Project Team}}</ref> | | author = Ring Laser Gyro Navigator Project Team}}</ref> | ||
==References== | ==References== | ||
{{reflist}} | {{reflist}} | ||
Latest revision as of 07:30, 18 March 2024
| This article may be deleted soon. | ||
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 Inertial navigation is a technique of navigation that does not depend on external references such as compasses, celestial navigation|stars, gravity or GPS, but computes the present position by sensing the movement of the navigating platform from a precisely known starting point in space. The general approach is to use multiple gyroscopes as references for the axes of position, as well as for error correction, using accelerometers to sense the motion. There are two major types of inertial navigation sensors, gimballed, where the sensors can move, and strapdown, where they are bonded to the moving vehicle. The method is exceptionally important for precision-guided munitions, space vehicles, and military ships, submarines and aircraft, because it
Inertial navigation is well-established technique; it is not to be confused with the concept of inertial propulsion developed within the Russian space research program. Modes of operation
In practice, inertial information is combined with other sources, such as GPS satellite. Enabling technologiesEssential to inertial navigation are gyroscopes, accelerometers, and computers, as well as the mathematics of inertial position comutation. Gyroscopes, first used as non-magnetic compasses and as true vertical indicators in aviation, are the fundamental enabling technology. Inertial navigation greatly benefited when gyroscope technology moved beyond mechanical to optical techniques, which do not require moving parts and can be much smaller. Gyroscope-generated information includes:
MathematicsInertial navigation is referenced to a geodesy|geodetic coordinate system. Compass#Gyrocompasses|Gyrocompasses were precursors of full inertial navigation. A first major implementation was the Ship Inertial Navigation System aboard the first U.S. ballistic missile submarines, which needed absolutely precise position information for accurate missile launching, but whose operational security depended on not exposing themselves for star sights, radio navigation, etc. While the submarine systems have continued to improve, and intertial navigation became common on surface warships, the United States Navy became concerned that it had multiple systems (i.e., AN-|AN/WSN-5 aboard surface combatants, the AN-|AN/WSN-3 aboard submarines and the AN-|AN/WSN-1 aboard aircraft carriers) where one would do, and that much less expensive commercial-off-the-shelf components were available. The AN-|AN/WSN-7 Ring Laser Gyro Navigation System, will replace all three, which are 15-20 years old and for which it is increasingly difficult to obtain spare parts. [1] References
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