Editing Attitude indicator

{{Short description|Flight instrument which displays the aircraft's orientation relative to Earth's horizon}}{{Not to be confused with|altimeter}}{{Redirect|Artificial Horizon|the U2 album|Artificial Horizon (album)}}
{{multiple image
|image1 = Attitude Indicator.png
|image2 = AI aircraft orientation.png
|footer = AI with [[aircraft principal axes|pitch and roll]] reference lines (left) and the AI relationship to aircraft orientation (right)
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The '''attitude indicator''' ('''AI'''), also known as the '''gyro horizon''' or '''artificial horizon''', is a [[flight instrument]] that informs the [[pilot]] of the aircraft [[Orientation (geometry)|orientation]] relative to Earth's [[horizon]], and gives an immediate indication of the smallest orientation change. The miniature aircraft and horizon bar mimic the relationship of the aircraft relative to the actual horizon.<ref name="FAA2">{{cite book |title=Instrument Flying Handbook, FAA-H-8083-15B |date=2012 |publisher=U.S. Dept. of Transportation, FAA |page=5-17,5-19 |url=https://www.faa.gov/regulations_policies/handbooks_manuals/aviation/media/FAA-H-8083-15B.pdf}} {{PD-notice}}</ref><ref name="FAA1">{{cite book |title=Pilot's Handbook of Aeronautical Knowledge, FAA-H-8083-25B |date=2016 |publisher=U.S. Dept. of Transportation, FAA |page=8-16,8-18,8-19 |url=https://www.faa.gov/regulations_policies/handbooks_manuals/aviation/phak/media/10_phak_ch8.pdf}}</ref> It is a primary instrument for flight in [[instrument meteorological conditions]].<ref name=":2">{{Cite book|title=Guided Flight Discovery Private PilotJe|last=Jeppesen, A Boeing Company|publisher=Jeppesen|year=2007|isbn=978-0-88487-429-4|pages=2–66}}</ref><ref>https://www.faa.gov/regulations_policies/handbooks_manuals/aircraft/ AMT Handbook - Aircraft Instrument Systems page 10-56</ref>

Attitude is always presented to users in the unit [[Degree (angle)|degrees]] (°). However, inner workings such as sensors, data and calculations may use a mix of degrees and [[radian]]s, as scientists and engineers may prefer to work with radians.

==History==
Before the advent of aviation, artificial horizons were used in [[celestial navigation]]. Proposals of such devices based on gyroscopes, or spinning tops, date back to the 1740s,<ref>Jörg F. Wagner: ''From Bohnenberger's Machine to Integrated Navigation Systems. 200 Years of Inertial Navigation.'' Photogrammetric Week 05. {{Cite web |url=http://www.ifp.uni-stuttgart.de/publications/phowo05/160wagner.pdf |title=Photogrammetric Week 2005 |access-date=2022-12-04 |archive-date=2007-07-06 |archive-url=https://web.archive.org/web/20070706205209/http://www.ifp.uni-stuttgart.de/publications/phowo05/160wagner.pdf |url-status=live }}</ref> including the work of [[John Serson]]. Later implementations, also known as ''bubble horizons'', were based on bubble levels and attached to a [[sextant]].<ref>I.C.B. Dear, Peter Kemp (ed.): ''The Oxford Companion to Ships and the Sea'', Oxford University Press, 2016, pp. 22, 77</ref> In the 2010s, remnants of an artificial horizon using liquid mercury were recovered from the wreck of [[HMS Erebus (1826)|HMS ''Erebus'']].<ref>[https://parks.canada.ca/lhn-nhs/nu/epaveswrecks/culture/archeologie-archeology/artefacts-artifacts/2015#21 2015 Artifacts], [https://parks.canada.ca/lhn-nhs/nu/epaveswrecks/culture/archeologie-archeology/artefacts-artifacts/2018#18-03 2018 Artifacts], Wrecks of HMS Erebus and HMS Terror National Historic Site</ref>

==Use==
[[File:Attitude Indicator Interior.png|thumb|AI interior]]
The essential components of the AI include a symbolic miniature aircraft mounted so that it appears to be flying relative to the horizon. An adjustment knob, to account for the pilot's line of vision, moves the aircraft up and down to align it against the horizon bar. The top half of the instrument is blue to represent the sky, while the bottom half is brown to represent the ground. The bank index at the top shows the aircraft angle of bank. Reference lines in the middle indicate the degree of pitch, up or down, relative to the horizon.<ref name=FAA1/><ref name=FAA2/>

Most Russian-built aircraft have a somewhat different design. The background display is colored as in a Western instrument, but moves up and down only to indicate pitch. A symbol representing the aircraft (which is fixed in a Western instrument) rolls left or right to indicate bank angle.<ref>{{citation|last=Learmount|first=David |title=Which way is up for Eastern and Western artificial horizons? |url=http://www.flightglobal.com/blogs/learmount/2009/02/which_way_is_up_for_eastern_an/ |work=flightglobal.com |date=2009-02-09 |url-status=dead |archive-url=https://web.archive.org/web/20141029214654/http://www.flightglobal.com/blogs/learmount/2009/02/which_way_is_up_for_eastern_an/ |archive-date=October 29, 2014 }}</ref> A proposed hybrid version of the Western and Russian systems would be more intuitive, but has never caught on.<ref>[https://web.archive.org/web/20130625220312/http://www.flightglobal.com/news/articles/safety-expert-proposes-low-cost-loss-of-control-fixes-353929 Safety expert proposes low-cost loss of control fixes ], [[FlightGlobal]], 2011-03-04</ref>

==Operation==
[[File:Vacuum Pump system.png|thumb|upright=1.5|Vacuum system using a vacuum pump]]
[[File:Venturi vacuum.png|thumb|upright=.8|Vacuum system using a venturi]]
The heart of the AI is a [[gyroscope]] (gyro) that spins at high speed, from either an electric motor, or through the action of a stream of air pushing on rotor vanes placed along its periphery. The stream of air is provided by a vacuum system, driven by a vacuum pump, or a venturi. Air passing through the narrowest portion of a venturi has lower air pressure through [[Bernoulli's principle]]. The gyro is mounted in a double gimbal, which allows the aircraft to pitch and roll as the gyro stays vertically upright. A self-erecting mechanism, actuated by gravity, counteracts any [[precession]] due to [[bearing (mechanical)|bearing friction]]. It may take a few minutes for the erecting mechanism to bring the gyros to a vertical upright position after the aircraft engine is first powered up.<ref name=FAA1/><ref name=FAA2/><ref name=":3">{{Cite web|url=https://www.faa.gov/regulations_policies/handbooks_manuals/aircraft/|title=AMT Handbook - Chapter 10. Aircraft Instrument Systems|last=Federal Aviation Administration (FAA)}}</ref>

Attitude indicators have mechanisms that keep the instrument level with respect to the direction of gravity.<ref>{{cite web|url=http://www.faatest.com/books/IFRH/4-4.htm|title=4-4|first=alan|last=murphy|website=www.faatest.com|access-date=22 March 2018}}</ref> The instrument may develop small errors, in pitch or bank during extended periods of acceleration, deceleration, turns, or due to the earth curving underneath the plane on long trips. To start with, they often have slightly more weight in the bottom, so that when the aircraft is resting on the ground they will hang level and therefore they will be level when started. But once they are started, that pendulous weight in the bottom will not pull them level if they are out of level, but instead its pull will cause the gyro to [[precession|precess]]. In order to let the gyro very slowly orient itself to the direction of gravity while in operation, the typical vacuum powered gyro has small pendulums on the rotor casing that partially cover air holes. When the gyro is out of level with respect to the direction of gravity, the pendulums will swing in the direction of gravity and either uncover or cover the holes, such that air is allowed or prevented from jetting out of the holes, and thereby applying a small force to orient the gyro towards the direction of gravity. Electric powered gyros may have different mechanisms to achieve a similar effect.<ref>{{cite web|url=http://www.faatest.com/books/IFRH/4-5.htm|title=4-5|first=alan|last=murphy|website=www.faatest.com|access-date=22 March 2018}}</ref>

Older AIs were limited in the amount of pitch or roll that they would tolerate. Exceeding these limits would cause the gyro to tumble as the gyro housing contacted the gimbals, causing a precession force. Preventing this required a caging mechanism to lock the gyro if the pitch exceed 60° and the roll exceeded 100°. Modern AIs do not have this limitation and therefore do not require a caging mechanism.<ref name=FAA1/><ref name=FAA2/>

Attitude indicators are free from most errors, but depending upon the speed with which the erection system functions, there may be a slight nose-up indication during a rapid acceleration and a nose-down indication during a rapid deceleration. There is also a possibility of a small bank angle and pitch error after a 180° turn. These inherent errors are small and correct themselves within a minute or so after returning to straight-and-level flight.<ref name=FAA2 />

==Flight Director Attitude Indicator==
{{multiple image
|image1 = Apollo FDAI.png
|image2 = Apollo Inertial Measurement Unit.png
|footer = Apollo Flight Director Attitude Indicator (left) and [[Inertial Measurement Unit]] (IMU) (right)
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Attitude indicators are also used on crewed spacecraft and are called '''Flight Director Attitude Indicators''' (FDAI), where they indicate the craft's yaw angle (nose left or right), pitch (nose up or down), roll, and orbit relative to a fixed-space [[inertial reference frame]] from an Inertial Measurement Unit (IMU).<ref name=":0">{{Cite web|url=https://www.hq.nasa.gov/alsj/alsj-FDAI.html|title=Flight-Director/{{sic|Ati|tude|nolink=y}} Indicator|website=www.hq.nasa.gov|access-date=2016-12-01}}</ref> The FDAI can be configured to use known positions relative to Earth or the stars, so that the engineers, scientists and astronauts can communicate the relative position, attitude, and orbit of the craft.<ref name=":1">{{Cite web|url=https://history.nasa.gov/afj/aohindex.htm|title=Apollo Flight Journal - Apollo Operations Handbook. Volume 1.|website=history.nasa.gov|access-date=2016-12-01|archive-url=https://web.archive.org/web/20151224133217/http://history.nasa.gov/afj/aohindex.htm|archive-date=2015-12-24|url-status=dead}}</ref><ref>{{cite journal |title=Apollo Guidance, Navigation, and Control (GNC) Hardware Overview |url=https://ntrs.nasa.gov/archive/nasa/casi.ntrs.nasa.gov/20090016290.pdf |website=NASA Technical Reports Server |date=January 2009 |publisher=NASA |access-date=12 October 2018|last1=Interbartolo |first1=Michael }}</ref>

==Attitude and Heading Reference Systems==
[[AHRS|Attitude and Heading Reference Systems (AHRS)]] are able to provide three-axis information based on [[ring laser gyroscope]]s, that can be shared with multiple devices in the aircraft, such as "[[glass cockpit]]" primary flight displays ([[Primary flight display|PFD]]s). Rather than using a spinning gyroscope, modern AHRS use [[solid-state electronics]], low-cost [[inertial sensor]]s, [[rate gyro]]s, and [[magnetometer]]s.<ref name=FAA1/>{{rp|8–20}}<ref name=FAA2/>{{rp|5–22}}

With most AHRS systems, if an aircraft's AIs have failed there will be a standby AI located in the center of the instrument panel, where other standby basic instruments such as the airspeed indicator and altimeter are also available. These mostly mechanical standby instruments may remain available even if the electronic flight instruments fail, although the standby attitude indicator may be electrically driven and will, after a short time, fail if its electrical power fails.<ref>{{Cite web |title=NTSB Safety Recommendation |url=https://www.ntsb.gov/publications/_layouts/ntsb.recsearch/Recommendation.aspx?Rec=A-08-054|date=2010-11-08}}</ref>

==Attitude Direction Indicator==
{{multiple image
|image1 = ADI.png
|image2 = VMS Artificial Horizon.jpg
|footer = ADI (left) with yellow V steering bars, and an AI integrated with [[Instrument Landing System|ILS]] glide slope and localizer indicators (right) 
|total_width = 400
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The Attitude Direction Indicator (ADI), or Flight Director Indicator (FDI), is an AI integrated with a Flight Director System (FDS). The ADI incorporates a computer that receives information from the navigation system, such as the AHRS, and processes this information to provide the pilot with a 3-D flight trajectory cue to maintain a desired path. The cue takes the form of V steering bars. The aircraft is represented by a delta symbol and the pilot flies the aircraft so that the delta symbol is placed within the V steering bars.<ref name=FAA2/>{{rp|5-23,5-24}}

==See also==
*[[Acronyms and abbreviations in avionics]]
*[[Air India Flight 855]]
*[[Korean Air Cargo Flight 8509]]
*[[Peripheral vision horizon display]] (PVHD)
*[[Turn and slip indicator]]

== References ==
{{Reflist}}

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{{Flight instruments}}
{{Aircraft components}}
{{Authority control}}

[[Category:Avionics]]
[[Category:Navigational flight instruments]]
[[Category:Technology systems]]