Adverse yaw: Difference between revisions
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'''Adverse yaw''' is the natural and undesirable tendency for an [[aircraft]] to [[Aircraft principal axes#Vertical axis .28yaw.29|yaw]] in the opposite direction of a [[Aircraft principal axes#Longitudinal axis .28roll.29|roll]]. It is caused by |
'''Adverse yaw''' is the natural and undesirable tendency for an [[aircraft]] to [[Aircraft principal axes#Vertical axis .28yaw.29|yaw]] in the opposite direction of a [[Aircraft principal axes#Longitudinal axis .28roll.29|roll]]. It is caused by the difference in lift and drag of each wing. The effect can be greatly minimized with [[aileron]]s deliberately designed to create drag when deflected upward and/or mechanisms which automatically apply some amount of coordinated [[rudder]]. As the major causes of adverse yaw vary with lift, any fixed-ratio mechanism will fail to fully solve the problem across all flight conditions and thus any manually operated aircraft will require some amount of [[rudder]] input from the pilot in order to maintain [[coordinated flight]]. |
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==History== |
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Adverse yaw was first experienced by the Wright brothers when they were unable to perform controlled turns in [[Wright Glider#1901 glider|their 1901 glider]] which had no vertical control surface. Orville Wright later described the glider's lack of directional control.<ref>"How we invented the airplane", Orville Wright, page 16</ref> |
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== Causes == |
== Causes == |
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Adverse yaw is a secondary effect of the inclination of the [[Lift (force)|lift]] vectors on the wing due to its rolling velocity and of the application of the ailerons.<ref name=perkins-hage>Perkins, Courtland; Hage, Robert (1949). ''Airplane performance, stability and control''. John Wiley and Sons. ISBN |
Adverse yaw is a secondary effect of the inclination of the [[Lift (force)|lift]] vectors on the wing due to its rolling velocity and of the application of the ailerons.<ref name=perkins-hage>Perkins, Courtland; Hage, Robert (1949). ''Airplane performance, stability and control''. John Wiley and Sons. {{ISBN|0-471-68046-X}}.</ref>{{rp|327}} Some pilot training manuals focus mainly on the additional drag caused by the downward-deflected aileron<ref name=langewiesche>Langewiesche, Wolfgang (1944). ''Stick and Rudder''. McGraw-Hill. pp. 163–165. {{ISBN|0-07-036240-8}}.</ref><ref name=faa-phoan>[http://www.faa.gov/library/manuals/aviation/pilot_handbook/media/PHAK%20-%20Chapter%2005.pdf ''Pilot's Handbook of Aeronautical Knowledge Ch. 5''] {{webarchive |url=https://web.archive.org/web/20121101185310/http://www.faa.gov/library/manuals/aviation/pilot_handbook/media/PHAK%20-%20Chapter%2005.pdf |date=November 1, 2012 }}, Federal Aviation Administration, 2008, p. 5-3, retrieved 2012-12-12</ref> |
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and make only brief{{#tag:ref |
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|'An expert will object here and point out that the ailerons cannot be held wholly responsible for the adverse yaw effect; that some of this adverse yawing tendency is due simply to the rolling motion of the wings and would persist no matter what device might cause the wings to roll. But the explanation just given answers the purposes of the pilot. Even though it does not tell the whole truth, it tells truth, and it has the advantage that it can be "shown."'<ref name=langewiesche/> |
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}} or indirect{{#tag:ref |
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}} mentions of roll effects. In fact the rolling of the wings usually causes a greater effect than the ailerons.{{#tag:ref |
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}} Assuming a roll rate to the right, as in the diagram, the causes are explained as follows: |
}} Assuming a roll rate to the right, as in the diagram, the causes are explained as follows: |
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[[Image:Adverse yaw.png|right]] |
[[Image:Adverse yaw.png|thumb|right|400px|]] |
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===Lift |
===Lift vector deflection during rolling=== |
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During a positive rolling motion, the left wing moves upward. If an aircraft were somehow suspended in air with no motion other than a positive roll, then from the point of view of the left wing, air will be coming from above and striking the upper surface of the wing. Thus, the left wing will experience a small amount of oncoming airflow merely from the rolling motion. This can be conceptualized as a vector originating from the left wing and pointing towards the oncoming air during the positive roll, i.e. perpendicularly upwards from the left wing's surface. If this positive-rolling aircraft were additionally moving forward in flight, then the vector pointing towards the oncoming air will be mostly forward due to forward-moving flight, but also slightly upward due to the rolling motion. This is the dashed vector coming from the left wing in the diagram. |
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By definition, lift is perpendicular to the oncoming flow.<ref name="perkins-hage" />{{rp|18}} As the left wing moves up, its effective [[angle of attack]] is decreased,<ref name="perkins-hage" />{{rp|361}} so its lift vector tilts back. Conversely, as the right wing descends, its lift vector tilts forward. The result is an adverse yaw moment to the left, opposite to the intended right turn. |
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Thus, for the left wing of a forward-moving aircraft, a positive roll causes the oncoming air to be deflected slightly upwards. Equivalently, the left wing's effective [[angle of attack]] is decreased due to the positive roll.<ref name="perkins-hage" />{{rp|361}} By definition, lift is perpendicular to the oncoming flow.<ref name="perkins-hage" />{{rp|18}} The upward deflection of oncoming air causes the lift vector to be deflected ''backward''. Conversely, as the right wing descends, its vector pointing towards the oncoming air is deflected downward and its lift vector is deflected ''forward''. The backward deflection of lift for the left wing and the forward deflection of lift for the right wing results in an adverse yaw moment to the left, opposite to the intended right turn. This adverse yaw moment is present only while the aircraft is rolling relative to the surrounding air, and disappears when the aircraft's bank angle is steady. |
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| ⚫ | The downward aileron deflection on the left increases the [[airfoil]] camber, which will typically increase the [[profile drag]]. Conversely, the upward aileron deflection on the right will decrease the camber and profile drag. The profile drag imbalance adds to the adverse yaw. |
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===Induced drag=== |
===Induced drag=== |
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Initiating a roll to the right requires a briefly greater lift on the left than the right. This also causes a greater [[induced drag]] on the left than the right, which further adds to the adverse yaw, but only briefly. Once a steady roll rate is established the left/right lift imbalance dwindles,<ref name="perkins-hage" />{{rp|351}} while the other mechanisms described above persist. |
Initiating a roll to the right requires a briefly greater lift on the left than the right. This also causes a greater [[induced drag]] on the left than the right, which further adds to the adverse yaw, but only briefly. Once a steady roll rate is established the left/right lift imbalance dwindles,<ref name="perkins-hage" />{{rp|351}} while the other mechanisms described above persist. |
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| ⚫ | The downward aileron deflection on the left increases the [[airfoil]] camber, which will typically increase the [[profile drag]]. Conversely, the upward aileron deflection on the right will decrease the camber and profile drag. The profile drag imbalance adds to the adverse yaw. A Frise aileron reduces this imbalance drag, as described further below. |
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== Minimizing the adverse yaw == |
== Minimizing the adverse yaw == |
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There are a number of aircraft design characteristics which can be used to reduce adverse yaw to ease the pilot workload: |
There are a number of aircraft design characteristics which can be used to reduce adverse yaw to ease the pilot workload: |
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=== |
=== Yaw stability=== |
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| ⚫ | A strong directional stability is the first way to reduce adverse yaw.<ref name=azbug>Airplane Stability and Control, Abzug and Larrabee, page 64. "Adverse yaw must be overcome by good directional stability complemented by rudder deflection".</ref> This is influenced by the vertical tail moment (area and lever arm about gravity center). |
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===Lift coefficient=== |
===Lift coefficient=== |
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As the tilting of the left/right lift vectors is the major cause to adverse yaw, an important parameter is the magnitude of these lift vectors, or the aircraft's [[lift coefficient]] to be more specific. Flight at low lift coefficient (or high speed compared to minimum speed) produces less adverse yaw.<ref name=perkins-hage/>{{rp|365}} |
As the tilting of the left/right lift vectors is the major cause to adverse yaw, an important parameter is the magnitude of these lift vectors, or the aircraft's [[lift coefficient]] to be more specific. Flight at low lift coefficient (or high speed compared to minimum speed) produces less adverse yaw.<ref name=perkins-hage/>{{rp|365}} |
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===Aileron to rudder mixing=== |
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| ⚫ | A strong directional stability is the first way to reduce adverse yaw.<ref name=azbug>Airplane Stability and Control, Abzug and Larrabee, page 64. "Adverse yaw must be overcome by good directional stability complemented by rudder deflection".</ref> This is influenced by the vertical tail moment (area and lever arm about gravity center). |
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=== Differential aileron deflection === |
=== Differential aileron deflection === |
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The geometry of most aileron linkages can be configured so as to bias the travel further upward than downward. By excessively deflecting the upward aileron, profile drag is increased rather than reduced and [[Flow separation|separation drag]] further aids in producing drag on the inside wing, producing a yaw force in the direction of the turn. Though not as efficient as rudder mixing, aileron differential is very easy to implement on almost any airplane and offers the significant advantage of reducing the tendency for the wing to [[Stall (flight)|stall]] at the tip first by limiting the downward aileron deflection and its associated effective increase in angle of attack. |
The geometry of most aileron linkages can be configured so as to bias the travel further upward than downward. By excessively deflecting the upward aileron, profile drag is increased rather than reduced and [[Flow separation|separation drag]] further aids in producing drag on the inside wing, producing a yaw force in the direction of the turn. Though not as efficient as rudder mixing, aileron differential is very easy to implement on almost any airplane and offers the significant advantage of reducing the tendency for the wing to [[Stall (flight)|stall]] at the tip first by limiting the downward aileron deflection and its associated effective increase in angle of attack. |
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Most airplanes use this method of adverse yaw mitigation due to the simple implementation and safety benefits. |
Most airplanes use this method of adverse yaw mitigation — particularly noticeable on one of the first well-known aircraft to ever use them, the [[de Havilland Tiger Moth]] training biplane of the 1930s — due to the simple implementation and safety benefits. |
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=== Frise ailerons === |
=== Frise ailerons === |
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Frise ailerons are designed so that when up aileron is applied, some of the forward edge of the aileron will protrude downward into the airflow, causing increased drag on this (down-going) wing. This will counter the drag produced by the other aileron, thus reducing adverse yaw. |
Frise ailerons are designed so that when up aileron is applied, some of the forward edge of the aileron will protrude downward into the airflow, causing increased drag on this (down-going) wing. This will counter the drag produced by the other aileron, thus reducing adverse yaw. |
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Unfortunately, as well as reducing adverse yaw, Frise ailerons will increase the overall drag of the aircraft much more than applying rudder correction. Therefore they are less popular in aircraft where minimizing drag is important (e.g. in a [[Glider (sailplane)|glider]]). |
Unfortunately, as well as reducing adverse yaw, Frise ailerons will increase the overall drag of the aircraft much more than applying rudder correction. Therefore, they are less popular in aircraft where minimizing drag is important (e.g. in a [[Glider (sailplane)|glider]]). |
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Note |
Note: Frise ailerons were primarily designed to reduce roll control forces. Contrary to the illustration, the aileron leading edge is in fact rounded to prevent flow separation and [[aeroelasticity|flutter]] at negative deflections.<ref>Wind-tunnel tests of ailerons at various speeds, W. Letko and W.B. Kemp, NACA WR-L 325</ref> That prevents important differential drag forces. |
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{{clear}} |
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=== Roll spoilers === |
=== Roll spoilers === |
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On large aircraft where rudder use is inappropriate at high speeds or ailerons are too small at low speeds, roll spoilers can be used to minimise adverse yaw or increase roll moment. To function as a lateral control, the spoiler is raised on the down-going wing (up aileron) and remains retracted on the other wing. The raised spoiler increases the drag, and so the yaw is in the same direction as the roll.<ref>Oxford Aviation Academy (2007), JAA ATPL 13: Principles of Flight, Transair</ref> |
On large aircraft where rudder use is inappropriate at high speeds or ailerons are too small at low speeds, roll spoilers (also called [[spoileron]]s) can be used to minimise adverse yaw or increase roll moment. To function as a lateral control, the spoiler is raised on the down-going wing (up aileron) and remains retracted on the other wing. The raised spoiler increases the drag, and so the yaw is in the same direction as the roll.<ref>Oxford Aviation Academy (2007), JAA ATPL 13: Principles of Flight, Transair</ref> |
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{{clear}} |
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==References and notes== |
==References and notes== |
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{{DEFAULTSORT:Adverse Yaw}} |
{{DEFAULTSORT:Adverse Yaw}} |
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[[Category:Aerodynamics]] |
[[Category:Aerodynamics]] |
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[[Category:Gliding technology]] |
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Revision as of 06:42, 18 June 2024
Adverse yaw is the natural and undesirable tendency for an aircraft to yaw in the opposite direction of a roll. It is caused by the difference in lift and drag of each wing. The effect can be greatly minimized with ailerons deliberately designed to create drag when deflected upward and/or mechanisms which automatically apply some amount of coordinated rudder. As the major causes of adverse yaw vary with lift, any fixed-ratio mechanism will fail to fully solve the problem across all flight conditions and thus any manually operated aircraft will require some amount of rudder input from the pilot in order to maintain coordinated flight.
History
Adverse yaw was first experienced by the Wright brothers when they were unable to perform controlled turns in their 1901 glider which had no vertical control surface. Orville Wright later described the glider's lack of directional control.[1]
Causes
Adverse yaw is a secondary effect of the inclination of the lift vectors on the wing due to its rolling velocity and of the application of the ailerons.[2]: 327 Some pilot training manuals focus mainly on the additional drag caused by the downward-deflected aileron[3][4] and make only brief[5] or indirect[6] mentions of roll effects. In fact the rolling of the wings usually causes a greater effect than the ailerons.[8] Assuming a roll rate to the right, as in the diagram, the causes are explained as follows:
Lift vector deflection during rolling
During a positive rolling motion, the left wing moves upward. If an aircraft were somehow suspended in air with no motion other than a positive roll, then from the point of view of the left wing, air will be coming from above and striking the upper surface of the wing. Thus, the left wing will experience a small amount of oncoming airflow merely from the rolling motion. This can be conceptualized as a vector originating from the left wing and pointing towards the oncoming air during the positive roll, i.e. perpendicularly upwards from the left wing's surface. If this positive-rolling aircraft were additionally moving forward in flight, then the vector pointing towards the oncoming air will be mostly forward due to forward-moving flight, but also slightly upward due to the rolling motion. This is the dashed vector coming from the left wing in the diagram.
Thus, for the left wing of a forward-moving aircraft, a positive roll causes the oncoming air to be deflected slightly upwards. Equivalently, the left wing's effective angle of attack is decreased due to the positive roll.[2]: 361 By definition, lift is perpendicular to the oncoming flow.[2]: 18 The upward deflection of oncoming air causes the lift vector to be deflected backward. Conversely, as the right wing descends, its vector pointing towards the oncoming air is deflected downward and its lift vector is deflected forward. The backward deflection of lift for the left wing and the forward deflection of lift for the right wing results in an adverse yaw moment to the left, opposite to the intended right turn. This adverse yaw moment is present only while the aircraft is rolling relative to the surrounding air, and disappears when the aircraft's bank angle is steady.
Induced drag
Initiating a roll to the right requires a briefly greater lift on the left than the right. This also causes a greater induced drag on the left than the right, which further adds to the adverse yaw, but only briefly. Once a steady roll rate is established the left/right lift imbalance dwindles,[2]: 351 while the other mechanisms described above persist.
Profile drag
The downward aileron deflection on the left increases the airfoil camber, which will typically increase the profile drag. Conversely, the upward aileron deflection on the right will decrease the camber and profile drag. The profile drag imbalance adds to the adverse yaw. A Frise aileron reduces this imbalance drag, as described further below.
Minimizing the adverse yaw
There are a number of aircraft design characteristics which can be used to reduce adverse yaw to ease the pilot workload:
Yaw stability
A strong directional stability is the first way to reduce adverse yaw.[7] This is influenced by the vertical tail moment (area and lever arm about gravity center).
Lift coefficient
As the tilting of the left/right lift vectors is the major cause to adverse yaw, an important parameter is the magnitude of these lift vectors, or the aircraft's lift coefficient to be more specific. Flight at low lift coefficient (or high speed compared to minimum speed) produces less adverse yaw.[2]: 365
Aileron to rudder mixing
As intended, the rudder is the most powerful and efficient means of managing yaw but mechanically coupling it to the ailerons is impractical. Electronic coupling is commonplace in fly-by-wire aircraft.
Differential aileron deflection
The geometry of most aileron linkages can be configured so as to bias the travel further upward than downward. By excessively deflecting the upward aileron, profile drag is increased rather than reduced and separation drag further aids in producing drag on the inside wing, producing a yaw force in the direction of the turn. Though not as efficient as rudder mixing, aileron differential is very easy to implement on almost any airplane and offers the significant advantage of reducing the tendency for the wing to stall at the tip first by limiting the downward aileron deflection and its associated effective increase in angle of attack.
Most airplanes use this method of adverse yaw mitigation — particularly noticeable on one of the first well-known aircraft to ever use them, the de Havilland Tiger Moth training biplane of the 1930s — due to the simple implementation and safety benefits.
Frise ailerons
Frise ailerons are designed so that when up aileron is applied, some of the forward edge of the aileron will protrude downward into the airflow, causing increased drag on this (down-going) wing. This will counter the drag produced by the other aileron, thus reducing adverse yaw.
Unfortunately, as well as reducing adverse yaw, Frise ailerons will increase the overall drag of the aircraft much more than applying rudder correction. Therefore, they are less popular in aircraft where minimizing drag is important (e.g. in a glider).
Note: Frise ailerons were primarily designed to reduce roll control forces. Contrary to the illustration, the aileron leading edge is in fact rounded to prevent flow separation and flutter at negative deflections.[9] That prevents important differential drag forces.
Roll spoilers
On large aircraft where rudder use is inappropriate at high speeds or ailerons are too small at low speeds, roll spoilers (also called spoilerons) can be used to minimise adverse yaw or increase roll moment. To function as a lateral control, the spoiler is raised on the down-going wing (up aileron) and remains retracted on the other wing. The raised spoiler increases the drag, and so the yaw is in the same direction as the roll.[10]
References and notes
Collection of balanced-aileron test data, F.M. Rogallo, Naca WR-L 419
- ^ "How we invented the airplane", Orville Wright, page 16
- ^ a b c d e Perkins, Courtland; Hage, Robert (1949). Airplane performance, stability and control. John Wiley and Sons. ISBN 0-471-68046-X.
- ^ a b Langewiesche, Wolfgang (1944). Stick and Rudder. McGraw-Hill. pp. 163–165. ISBN 0-07-036240-8.
- ^ a b Pilot's Handbook of Aeronautical Knowledge Ch. 5 Archived November 1, 2012, at the Wayback Machine, Federal Aviation Administration, 2008, p. 5-3, retrieved 2012-12-12
- ^ 'An expert will object here and point out that the ailerons cannot be held wholly responsible for the adverse yaw effect; that some of this adverse yawing tendency is due simply to the rolling motion of the wings and would persist no matter what device might cause the wings to roll. But the explanation just given answers the purposes of the pilot. Even though it does not tell the whole truth, it tells truth, and it has the advantage that it can be "shown."'[3]
- ^ 'The adverse yaw is a result of differential drag and the slight difference in the velocity of the left and right wings.'[4]
- ^ a b Airplane Stability and Control, Abzug and Larrabee, page 64. "Adverse yaw must be overcome by good directional stability complemented by rudder deflection".
- ^ 'for normal wing plan forms with aspect ratios above about 6, adverse yaw is actually dominated by the aerodynamic yawing moment due to rolling'[7]
- ^ Wind-tunnel tests of ailerons at various speeds, W. Letko and W.B. Kemp, NACA WR-L 325
- ^ Oxford Aviation Academy (2007), JAA ATPL 13: Principles of Flight, Transair