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{{Short description|Device which measures fluid flow velocity, typically around an aircraft or boat}}
{{cleanup HTML|date=February 2019}}
[[Image:Airspeed p1230157.jpg|thumb|Aircraft use pitot tubes to measure airspeed. The example, from an [[Airbus A380]], combines a pitot tube (right) with a static port and an [[angle-of-attack]] vane (left). Air-flow is right to left.]]
[[File:Airspeed p1230157.jpg|thumb|Aircraft use pitot tubes to measure airspeed. This example, from an [[Airbus A380]], combines a pitot tube (right) with a static port and an [[angle-of-attack]] vane (left). Air-flow is right to left.]]
[[Image:Pilot tube types.svg|thumb|right|Types of pitot tubes]]
[[File:Pitot tube types.svg|thumb|right|Types of pitot tubes]]
[[Image:pitot_tube_manometer.svg|thumb|A pitot-static tube connected to a manometer]]
[[File:pitot_tube_manometer.svg|thumb|A pitot-static tube connected to a manometer]]
[[Image:Pitot-cső helikopteren 4.jpg|thumb|Pitot tube on [[Kamov Ka-26]] helicopter]]
[[File:Pitot-cső helikopteren 4.jpg|thumb|Pitot tube on [[Kamov Ka-26]] helicopter]]
[[Image:Renault R25 (2005) Fernando Alonso pitot probe.jpg|thumb|Pitot tube on a Renault [[Formula One car]]]]
[[File:2020 Formula One tests Barcelona, Williams FW43, Russell, pitot tubes (cropped).jpg|thumb|A [[Formula One car]] during testing with frames holding many pitot tubes]]
[[File:B777-381 JA8752 nose Pitot tube ja.jpg|thumb|Location of pitot tubes on a [[Boeing 777]]]]
[[File:B777-381 JA8752 nose Pitot tube ja.jpg|thumb|Location of pitot tubes on a [[Boeing 777]]]]

A '''pitot''' ({{IPAc-en|ˈ|p|iː|t|oʊ}} {{respell|PEE|toh}}) '''tube''', also known as '''pitot probe''', is a [[flow measurement]] device used to measure [[fluid]] [[flow velocity]]. The pitot tube was invented by the [[France|French]] engineer [[Henri Pitot]] in the early 18th century<ref>{{cite journal|first= Henri |last=Pitot |year= 1732| title = Description d'une machine pour mesurer la vitesse des eaux courantes et le sillage des vaisseaux | journal = Histoire de l'Académie royale des sciences avec les mémoires de mathématique et de physique tirés des registres de cette Académie | pages = 363–376 | url = http://gallica.bnf.fr/ark:/12148/bpt6k35294.image.f543.langFR | format = PDF| accessdate = 2009-06-19}}</ref> and was modified to its modern form in the mid-19th century by French scientist [[Henry Darcy]].<ref>{{cite journal|first= Henry |last=Darcy |year= 1858| title = Note relative à quelques modifications à introduire dans le tube de Pitot | journal = Annales des Ponts et Chaussées | pages = 351–359 | url = http://gallica.bnf.fr/ark:/12148/bpt6k408489d.image.f354 | format = PDF| accessdate = 2009-07-31}}</ref> It is widely used to determine the [[airspeed]] of an [[aircraft]], water speed of a boat, and to measure liquid, air and gas flow velocities in certain industrial applications.
A '''pitot tube''' ({{IPAc-en|ˈ|p|iː|t|oʊ}} {{respell|PEE|toh}}; also '''pitot probe''') measures fluid [[flow velocity]]. It was invented by a French engineer, [[Henri Pitot]], in the early 18th century,<ref>{{cite journal|first= Henri |last=Pitot |year= 1732| title = Description d'une machine pour mesurer la vitesse des eaux courantes et le sillage des vaisseaux | journal = Histoire de l'Académie Royale des Sciences avec les mémoires de mathématique et de physique tirés des registres de cette Académie | pages = 363–376 | url = http://gallica.bnf.fr/ark:/12148/bpt6k35294.image.f543.langFR | format = PDF| access-date = 2009-06-19}}</ref> and was modified to its modern form in the mid-19th century by a French scientist, [[Henry Darcy]].<ref>{{cite journal|first= Henry |last=Darcy |year= 1858| title = Note relative à quelques modifications à introduire dans le tube de Pitot | journal = Annales des Ponts et Chaussées | pages = 351–359 | url = http://gallica.bnf.fr/ark:/12148/bpt6k408489d.image.f354 | format = PDF| access-date = 2009-07-31}}</ref> It is widely used to determine the [[airspeed]] of aircraft;<ref>{{Citation|title=Venturi effect and Pitot tubes {{!}} Fluids {{!}} Physics {{!}} Khan Academy| date=September 2014 |url=https://www.youtube.com/watch?v=Qz1g6kqvUG8|language=en|access-date=2019-12-15}}</ref> the water speed of boats; and the flow velocity of liquids, air, and gases in industry.


==Theory of operation==
==Theory of operation==
The basic pitot tube consists of a tube pointing directly into the fluid flow. As this tube contains fluid, a pressure can be measured; the moving fluid is brought to rest (stagnates) as there is no outlet to allow flow to continue. This pressure is the [[stagnation pressure]] of the fluid, also known as the total pressure or (particularly in aviation) the pitot pressure.
The basic pitot tube consists of a tube pointing directly into the fluid flow. As this tube contains fluid, a pressure can be measured; the moving fluid is brought to rest (stagnates) as there is no outlet to allow flow to continue. This pressure is the [[stagnation pressure]] of the fluid, also known as the total pressure or (particularly in aviation) the [[pitot pressure]].


The measured stagnation pressure cannot itself be used to determine the fluid flow velocity (airspeed in aviation). However, [[Bernoulli's equation]] states:
The measured stagnation pressure cannot itself be used to determine the fluid flow velocity (airspeed in aviation). However, [[Bernoulli's equation]] states:


<dl><dd>'''Stagnation pressure = static pressure + dynamic pressure'''</dd></dl>
:'''Stagnation pressure = static pressure + dynamic pressure'''


Which can also be written
Which can also be written


:<math>p_t = p_s + \left(\frac{\rho u^2}{2}\right) \,.</math>
:<math>p_t = p_s + \left(\frac{\rho u^2}{2}\right)</math>


Solving that for flow velocity gives
Solving that for flow velocity gives


:<math>u = \sqrt{\frac{2 (p_t - p_s)}{\rho}} \,,</math>
:<math>u = \sqrt{\frac{2 (p_t - p_s)}{\rho}}</math>


where
where
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In aircraft, the static pressure is generally measured using the [[static port]]s on the side of the fuselage. The dynamic pressure measured can be used to determine the [[indicated airspeed]] of the aircraft. The diaphragm arrangement described above is typically contained within the [[airspeed indicator]], which converts the dynamic pressure to an airspeed reading by means of mechanical levers.
In aircraft, the static pressure is generally measured using the [[static port]]s on the side of the fuselage. The dynamic pressure measured can be used to determine the [[indicated airspeed]] of the aircraft. The diaphragm arrangement described above is typically contained within the [[airspeed indicator]], which converts the dynamic pressure to an airspeed reading by means of mechanical levers.


Instead of separate pitot and static ports, a pitot-static tube (also called a [[Prandtl]] tube) may be employed, which has a second tube coaxial with the pitot tube with holes on the sides, outside the direct airflow, to measure the static pressure.<ref>[https://books.google.com/books?id=0SkDAAAAMBAJ&pg=PA116&dq=Popular+Science+The+lads+who+fly+Britain%27s+1944&hl=en&sa=X&ei=UHyfT6aEIYOs9ATwh8C1AQ&ved=0CDkQ6AEwAA#v=onepage&q&f=true "How Aircraft Instruments Work."] ''Popular Science'', March 1944, pp. 116.</ref>
Instead of separate pitot and static ports, a pitot-static tube (also called a [[Prandtl]] tube) may be employed, which has a second tube coaxial with the pitot tube with holes on the sides, outside the direct airflow, to measure the static pressure.<ref>[https://books.google.com/books?id=0SkDAAAAMBAJ&dq=Popular+Science+The+lads+who+fly+Britain%27s+1944&pg=PA116 "How Aircraft Instruments Work."] ''Popular Science'', March 1944, pp. 116.</ref>


If a liquid column [[Manometer#Liquid column|manometer]] is used to measure the pressure difference <math>\Delta p \equiv p_t - p_s</math>,
If a liquid column [[Manometer#Liquid column|manometer]] is used to measure the pressure difference <math>\Delta p \equiv p_t - p_s</math>,
:<math>\Delta h = \frac{\Delta p}{\rho_l g} \,, </math>
:<math>\Delta h = \frac{\Delta p}{\rho_l g}</math>
where
where
* <math>\Delta h</math> is the height difference of the columns;
* <math>\Delta h</math> is the height difference of the columns;
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Therefore,
Therefore,
:<math>u = \sqrt{\frac{2 \, \Delta h \, \rho_l g}{\rho}} \,.</math>
:<math>u = \sqrt{\frac{2 \, \Delta h \, \rho_l g}{\rho}}</math>


==Aircraft==
==Aircraft and accidents==
{{Main article|Pitot-static system}}
{{Main|Pitot–static system}}
A pitot-static system is a [[system]] of pressure-sensitive instruments that is most often used in aviation to determine an aircraft's [[airspeed]], [[Mach number]], [[altitude]], and [[Vertical speed indicator|altitude trend]]. A pitot-static system generally consists of a pitot tube, a static port, and the pitot-static instruments.<ref name="jepp">{{cite book|title=Guided Flight Discovery - Private Pilot|publisher=Jeppesen Sanderson|others=Abbot, Mike Kailey, Liz|year=2004|isbn=0-88487-333-1|pages=2–48–2–53|editor=Willits, Pat|origyear=1997}}</ref> Errors in pitot-static system readings can be extremely dangerous as the information obtained from the pitot static system, such as airspeed, is potentially safety-critical.
A pitot-static system is a [[system]] of pressure-sensitive instruments that is most often used in aviation to determine an aircraft's [[airspeed]], [[Mach number]], [[altitude]], and [[Vertical speed indicator|altitude trend]]. A pitot-static system generally consists of a pitot tube, a static port, and the pitot-static instruments.<ref name="jepp">{{cite book|title=Guided Flight Discovery - Private Pilot|publisher=Jeppesen Sanderson|others=Abbot, Mike Kailey, Liz|year=2004|isbn=0-88487-333-1|pages=2–48–2–53|editor=Willits, Pat|orig-year=1997}}</ref> Errors in pitot-static system readings can be extremely dangerous as the information obtained from the pitot static system, such as airspeed, is potentially safety-critical.


Several commercial airline incidents and accidents have been traced to a failure of the pitot-static system. Examples include [[Austral Líneas Aéreas Flight 2553]], [[Northwest Airlines Flight 6231]], [[Birgenair Flight 301]] and one of the two [[X-31]]s.<ref>[http://www.nasa.gov/centers/dryden/news/NewsReleases/1995/95-33_pf.html NASA Dryden news releases. (1995)]</ref> The French air safety authority [[Bureau d'Enquêtes et d'Analyses pour la Sécurité de l'Aviation Civile|BEA]] said that pitot tube icing was a contributing factor in the crash of [[Air France Flight 447]] into the [[Atlantic Ocean]].<ref>{{cite web |url=https://www.reuters.com/article/2012/07/05/uk-airfrance-crash-idUSLNE86402T20120705 |title=Training flaws exposed in Rio-Paris crash report |date=5 July 2012 |publisher=Reuters |accessdate=5 October 2012}}</ref> In 2008 [[Air Caraïbes]] reported two incidents of pitot tube icing malfunctions on its A330s.<ref>{{cite web |url= http://www.flightglobal.com/news/articles/air-caraibes-atlantique-memo-details-pitot-icing-incidents-327738/ |title=Air Caraibes Atlantique memo details pitot icing incidents |first=Kieran |last=Daly |work=Flight International |date=11 June 2009 |accessdate=19 February 2012}}</ref>
Several commercial airline incidents and accidents have been traced to a failure of the pitot-static system. Examples include [[Austral Líneas Aéreas Flight 2553]], [[Northwest Airlines Flight 6231]], [[Birgenair Flight 301]] and one of the two [[X-31]]s.<ref>{{cite web| url = http://www.nasa.gov/centers/dryden/news/NewsReleases/1995/95-33_pf.html| title = NASA Dryden news releases. (1995)}}</ref> The French air safety authority [[Bureau d'Enquêtes et d'Analyses pour la Sécurité de l'Aviation Civile|BEA]] said that pitot tube [[icing (aviation)|icing]] was a contributing factor in the crash of [[Air France Flight 447]] into the [[Atlantic Ocean]].<ref>{{cite news |url=https://www.reuters.com/article/uk-airfrance-crash-idUSLNE86402T20120705 |title=Training flaws exposed in Rio-Paris crash report |date=5 July 2012 |work=Reuters |access-date=5 October 2012}}</ref> In 2008 [[Air Caraïbes]] reported two incidents of pitot tube icing malfunctions on its A330s.<ref>{{cite web |url= http://www.flightglobal.com/news/articles/air-caraibes-atlantique-memo-details-pitot-icing-incidents-327738/ |title=Air Caraibes Atlantique memo details pitot icing incidents |first=Kieran |last=Daly |work=Flight International |date=11 June 2009 |access-date=19 February 2012}}</ref>


[[Birgenair Flight 301]] had a fatal pitot tube failure which investigators suspected was due to insects creating a nest inside the pitot tube; the prime suspect is the [[black and yellow mud dauber]] wasp.
[[Birgenair Flight 301]] had a fatal pitot tube failure which investigators suspected was due to insects creating a nest inside the pitot tube; the prime suspect is the [[black and yellow mud dauber]] wasp.


[[Aeroperú Flight 603]] had a pitot-static system failure due to the cleaning crew leaving the static port blocked with tape.
[[Aeroperú Flight 603]] had a fatal pitot-static system failure due to the cleaning crew leaving the static port blocked with tape.


== Industry applications ==
== Industry applications ==
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In aviation, airspeed is typically measured in [[knot (unit)|knot]]s.
In aviation, airspeed is typically measured in [[knot (unit)|knot]]s.


In weather stations with high wind speeds, the pitot tube is modified to create a special type of anemometer called [[pitot tube static anemometer]].<ref>{{cite web|title=Instrumentation: Pitot Tube Static Anemometer, Part 1|url=http://www.accuweather.com/en/weather-blogs/clarkb/instrumentation/14828|publisher=Mount Washington Observatory|accessdate=14 July 2014}}</ref>
In weather stations with high wind speeds, the pitot tube is modified to create a special type of anemometer called [[pitot tube static anemometer]].<ref>{{cite web|title=Instrumentation: Pitot Tube Static Anemometer, Part 1|url=http://www.accuweather.com/en/weather-blogs/clarkb/instrumentation/14828|publisher=Mount Washington Observatory|access-date=14 July 2014|archive-url=https://web.archive.org/web/20140714135450/http://www.accuweather.com/en/weather-blogs/clarkb/instrumentation/14828|archive-date=14 July 2014|url-status=dead}}</ref>


==See also==
==See also==
{{Columns-list|
{{col-begin}}{{col-break}}
*[[Air data boom]]
* [[Air data boom]]
*[[Altimeter]]
* [[Altimeter]]
*[[Annubar]]
* [[Annubar]]
* [[Calibrated airspeed]]
*[[Anti-icing]]
*[[Atmospheric icing]]
* [[Deicing]]
* [[Gyrocompass]]
*[[Calibrated airspeed]]
* [[Kiel probe]]
{{col-break}}
*[[Deicing]]
* [[Piezometer]]
*[[Flow measurement]]
* [[Position error]]
*[[Gyrocompass]]
* [[True airspeed]]
}}
*[[Icing conditions]]
*[[Kiel probe]]
*[[Mach number]]
{{col-break}}
*[[Piezometer]]
*[[Pitot-static system]]
*[[Position error]]
*[[Stagnation pressure]]
*[[True airspeed]]
{{col-end}}


==References==
==References==
'''Notes'''
===Notes===
{{reflist}}
{{reflist}}


'''Bibliography'''
===Bibliography===
*{{cite book|last=Kermode|first=A.C.|others=Barnard, R.H. (Ed.) and Philpott, D.R. (Ed.)|title=Mechanics of Flight|edition=10th|orig-year=1972|year=1996|publisher=Prentice Hall|isbn=0-582-23740-8|pages=63–67}}
{{refbegin}}
*{{cite book|last=Pratt|first=Jeremy M.|edition=3rd|title=The Private Pilot's Licence Course: Principles of Flight, Aircraft General Knowledge, Flight Performance and Planning|orig-year=1997|year=2005|isbn=1-874783-23-3|pages=gen108–gen111|publisher=Airplan Flight Equipment |no-pp=true}}
*{{cite book|last=Kermode|first=A.C.|others=Barnard, R.H. (Ed.) and Philpott, D.R. (Ed.)|title=Mechanics of Flight|edition=10th|origyear=1972|year=1996|publisher=Prentice Hall|isbn=0-582-23740-8|pages=63–67}}
*{{cite book|last=Pratt|first=Jeremy M.|edition=3rd|title=The Private Pilot's Licence Course: Principles of Flight, Aircraft General Knowledge, Flight Performance and Planning|origyear=1997|year=2005|isbn=1-874783-23-3|pages=gen108–gen111|nopp=true}}
*{{cite book|author=Tietjens, O.G.|title=Applied Hydro- and Aeromechanics, based on lectures of L. Prandtl, Ph.D| publisher=Dove Publications, Inc. | year=1934 | isbn=0-486-60375-X | pages=226–239}}
*{{cite book|author=Tietjens, O.G.|title=Applied Hydro- and Aeromechanics, based on lectures of L. Prandtl, Ph.D| publisher=Dove Publications, Inc. | year=1934 | isbn=0-486-60375-X | pages=226–239}}
*{{cite book|last=Saleh |first=J.M. |year=2002 |title=Fluid Flow Handbook |publisher=McGraw-Hill Professional}}
*{{cite book|last=Saleh |first=J.M. |year=2002 |title=Fluid Flow Handbook |publisher=McGraw-Hill Professional}}
{{refend}}


==External links==
==External links==
{{Commons|Pitot tube}}
{{Commons|Pitot tube}}
*[https://www.youtube.com/watch?v=D6sbzkYq3_c 3D animation of the Pitot Tube Differential Pressure Flow Measuring Principle]
* [https://www.youtube.com/watch?v=D6sbzkYq3_c 3D animation of the Pitot Tube Differential Pressure Flow Measuring Principle]
*[https://www.wired.com/autopia/2009/06/airspeed-sensors/ How 18th Century Technology Could Down an Airliner] (wired.com)
* [https://www.wired.com/autopia/2009/06/airspeed-sensors/ How 18th Century Technology Could Down an Airliner] (wired.com)

<!--spacing-->


{{Flight instruments}}
{{Flight instruments}}
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[[Category:Measuring instruments]]
[[Category:Measuring instruments]]
[[Category:French inventions]]
[[Category:French inventions]]
[[Category:Navigational flight instruments]]

Revision as of 18:24, 27 August 2024

Aircraft use pitot tubes to measure airspeed. This example, from an Airbus A380, combines a pitot tube (right) with a static port and an angle-of-attack vane (left). Air-flow is right to left.
Types of pitot tubes
A pitot-static tube connected to a manometer
Pitot tube on Kamov Ka-26 helicopter
A Formula One car during testing with frames holding many pitot tubes
Location of pitot tubes on a Boeing 777

A pitot tube (/ˈpt/ PEE-toh; also pitot probe) measures fluid flow velocity. It was invented by a French engineer, Henri Pitot, in the early 18th century,[1] and was modified to its modern form in the mid-19th century by a French scientist, Henry Darcy.[2] It is widely used to determine the airspeed of aircraft;[3] the water speed of boats; and the flow velocity of liquids, air, and gases in industry.

Theory of operation

The basic pitot tube consists of a tube pointing directly into the fluid flow. As this tube contains fluid, a pressure can be measured; the moving fluid is brought to rest (stagnates) as there is no outlet to allow flow to continue. This pressure is the stagnation pressure of the fluid, also known as the total pressure or (particularly in aviation) the pitot pressure.

The measured stagnation pressure cannot itself be used to determine the fluid flow velocity (airspeed in aviation). However, Bernoulli's equation states:

Stagnation pressure = static pressure + dynamic pressure

Which can also be written

Solving that for flow velocity gives

where

  • is the flow velocity;
  • is the stagnation or total pressure;
  • is the static pressure;
  • and is the fluid density.

NOTE: The above equation applies only to fluids that can be treated as incompressible. Liquids are treated as incompressible under almost all conditions. Gases under certain conditions can be approximated as incompressible. See Compressibility.

The dynamic pressure, then, is the difference between the stagnation pressure and the static pressure. The dynamic pressure is then determined using a diaphragm inside an enclosed container. If the air on one side of the diaphragm is at the static pressure, and the other at the stagnation pressure, then the deflection of the diaphragm is proportional to the dynamic pressure.

In aircraft, the static pressure is generally measured using the static ports on the side of the fuselage. The dynamic pressure measured can be used to determine the indicated airspeed of the aircraft. The diaphragm arrangement described above is typically contained within the airspeed indicator, which converts the dynamic pressure to an airspeed reading by means of mechanical levers.

Instead of separate pitot and static ports, a pitot-static tube (also called a Prandtl tube) may be employed, which has a second tube coaxial with the pitot tube with holes on the sides, outside the direct airflow, to measure the static pressure.[4]

If a liquid column manometer is used to measure the pressure difference ,

where

  • is the height difference of the columns;
  • is the density of the liquid in the manometer;
  • g is the standard acceleration due to gravity.

Therefore,

Aircraft and accidents

A pitot-static system is a system of pressure-sensitive instruments that is most often used in aviation to determine an aircraft's airspeed, Mach number, altitude, and altitude trend. A pitot-static system generally consists of a pitot tube, a static port, and the pitot-static instruments.[5] Errors in pitot-static system readings can be extremely dangerous as the information obtained from the pitot static system, such as airspeed, is potentially safety-critical.

Several commercial airline incidents and accidents have been traced to a failure of the pitot-static system. Examples include Austral Líneas Aéreas Flight 2553, Northwest Airlines Flight 6231, Birgenair Flight 301 and one of the two X-31s.[6] The French air safety authority BEA said that pitot tube icing was a contributing factor in the crash of Air France Flight 447 into the Atlantic Ocean.[7] In 2008 Air Caraïbes reported two incidents of pitot tube icing malfunctions on its A330s.[8]

Birgenair Flight 301 had a fatal pitot tube failure which investigators suspected was due to insects creating a nest inside the pitot tube; the prime suspect is the black and yellow mud dauber wasp.

Aeroperú Flight 603 had a fatal pitot-static system failure due to the cleaning crew leaving the static port blocked with tape.

Industry applications

Pitot tube from an F/A-18
Weather instruments at Mount Washington Observatory. Pitot tube static anemometer is on the right.

In industry, the flow velocities being measured are often those flowing in ducts and tubing where measurements by an anemometer would be difficult to obtain. In these kinds of measurements, the most practical instrument to use is the pitot tube. The pitot tube can be inserted through a small hole in the duct with the pitot connected to a U-tube water gauge or some other differential pressure gauge for determining the flow velocity inside the ducted wind tunnel. One use of this technique is to determine the volume of air that is being delivered to a conditioned space.

The fluid flow rate in a duct can then be estimated from:

Volume flow rate (cubic feet per minute) = duct area (square feet) × flow velocity (feet per minute)
Volume flow rate (cubic meters per second) = duct area (square meters) × flow velocity (meters per second)

In aviation, airspeed is typically measured in knots.

In weather stations with high wind speeds, the pitot tube is modified to create a special type of anemometer called pitot tube static anemometer.[9]

See also

References

Notes

  1. ^ Pitot, Henri (1732). "Description d'une machine pour mesurer la vitesse des eaux courantes et le sillage des vaisseaux" (PDF). Histoire de l'Académie Royale des Sciences avec les mémoires de mathématique et de physique tirés des registres de cette Académie: 363–376. Retrieved 2009-06-19.
  2. ^ Darcy, Henry (1858). "Note relative à quelques modifications à introduire dans le tube de Pitot" (PDF). Annales des Ponts et Chaussées: 351–359. Retrieved 2009-07-31.
  3. ^ Venturi effect and Pitot tubes | Fluids | Physics | Khan Academy, September 2014, retrieved 2019-12-15
  4. ^ "How Aircraft Instruments Work." Popular Science, March 1944, pp. 116.
  5. ^ Willits, Pat, ed. (2004) [1997]. Guided Flight Discovery - Private Pilot. Abbot, Mike Kailey, Liz. Jeppesen Sanderson. pp. 2–48–2–53. ISBN 0-88487-333-1.
  6. ^ "NASA Dryden news releases. (1995)".
  7. ^ "Training flaws exposed in Rio-Paris crash report". Reuters. 5 July 2012. Retrieved 5 October 2012.
  8. ^ Daly, Kieran (11 June 2009). "Air Caraibes Atlantique memo details pitot icing incidents". Flight International. Retrieved 19 February 2012.
  9. ^ "Instrumentation: Pitot Tube Static Anemometer, Part 1". Mount Washington Observatory. Archived from the original on 14 July 2014. Retrieved 14 July 2014.

Bibliography

  • Kermode, A.C. (1996) [1972]. Mechanics of Flight. Barnard, R.H. (Ed.) and Philpott, D.R. (Ed.) (10th ed.). Prentice Hall. pp. 63–67. ISBN 0-582-23740-8.
  • Pratt, Jeremy M. (2005) [1997]. The Private Pilot's Licence Course: Principles of Flight, Aircraft General Knowledge, Flight Performance and Planning (3rd ed.). Airplan Flight Equipment. gen108–gen111. ISBN 1-874783-23-3.
  • Tietjens, O.G. (1934). Applied Hydro- and Aeromechanics, based on lectures of L. Prandtl, Ph.D. Dove Publications, Inc. pp. 226–239. ISBN 0-486-60375-X.
  • Saleh, J.M. (2002). Fluid Flow Handbook. McGraw-Hill Professional.