thumb|upright=1.14|The empennage of an [[Atlas Air Boeing 747-200]]
The empennage ( or ), also known as the tail or tail assembly, is a structure at the rear of an aircraft that provides stability during flight, in a way similar to the feathers on an arrow. The term derives from the French language verb which means "to feather an arrow". Most aircraft feature an empennage incorporating vertical and horizontal stabilising surfaces which stabilise the flight dynamics of yaw and pitch,
The trim device may be:
- A trim tab on the rear of the elevators or rudder which act to change the aerodynamic load on the surface. Usually controlled by a cockpit wheel or crank.
- An adjustable stabiliser into which the stabiliser may be hinged at its spar and adjustably jacked a few degrees in incidence either up or down. Usually controlled by a cockpit crank.
Some locations have been given special names:
; Conventional tail : The vertical stabiliser and horizontal stabilisers are mounted to the rear of the fuselage. This is the simplest configuration that performs all three aspects of the function of a tail: trim, stability, and control. Around 60% of current aircraft designs — incorporate this type of tail. Examples are found on aircraft of every size and role, from general aviation types like the ubiquitous Cessna 172 to the largest airliners ever flown, such as the Airbus A380. Examples of this type of tail were in use as early as the Blériot VII of 1907.
; Cruciform tail : The horizontal stabilisers are placed midway up the vertical stabiliser, giving the appearance of a cross when viewed from the front. Cruciform tails are often used to keep the horizontal stabilisers out of the engine wake, while avoiding many of the disadvantages of a T-tail. Examples include the Hawker Sea Hawk and Douglas A-4 Skyhawk.
; T-tail : The horizontal stabiliser is mounted on top of the fin, creating a "T" shape when viewed from the front. T-tails keep the stabilisers out of the engine wake, and give better pitch control. T-tails have a good glide ratio, and are more efficient on low-speed aircraft. However, the T-tail has several disadvantages. It is more likely to enter a deep stall, and is more difficult to recover from a spin. For this reason a small secondary stabiliser or tail-let may be fitted lower down where it will be in free air when the aircraft is stalled. A T-tail must be stronger, and therefore heavier than a conventional tail. T-tails also tend to have a larger radar cross section. Examples include the Gloster Javelin and McDonnell Douglas DC-9.
{| align=center style="text-align:center;"
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|150px|alt=" "<br>Fuselage mounted
|150px|alt=" "<br>Cruciform
|150px|alt=" "<br>T-tail
|210px|alt=" "<br>Flying tailplane
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Fins
The fin comprises the fixed vertical stabiliser and rudder. Besides its profile, it is characterised by:
- Number of fins: usually one or two
- Location of fins: on the fuselage (over or under), tailplane, tail booms or wings
Twin fins may be mounted at various points:
- Twin tail A twin tail, also called an H-tail, consists of two small vertical stabilisers on either side of the horizontal stabiliser. Examples include the Antonov An-225 Mriya, B-25 Mitchell, Avro Lancaster, and ERCO Ercoupe.
- Twin boom A twin boom has two fuselages or booms, with a vertical stabiliser on each, and a horizontal stabiliser between them. Examples include the Northrop P-61 Black Widow, P-38 Lightning, de Havilland Sea Vixen, Sadler Vampire, and Edgley Optica.
- Wing mounted midwing as on the F7U Cutlass or on the wing tips as on the Handley Page Manx and Rutan Long-EZ
{| align=center style="text-align:center;"
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|150px|alt=" "<br>Tailplane mounted
|150px|alt=" "<br>Twin tail boom
|150px|alt=" "<br>Wing mounted
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Unusual fin configurations include:
- No fin – as on the McDonnell Douglas X-36. This configuration is sometimes incorrectly referred to as "tailless".
- Multiple fins – examples include the Lockheed Constellation (three), Bellanca 14-13 (three), and the Northrop Grumman E-2 Hawkeye (four).
- Ventral fin – underneath the fuselage. Often used in addition to a conventional fin as on the (North American X-15 and Dornier Do 335).
{| align=center style="text-align:center;"
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|150px|alt=" "<br>Triple fins
|210px|alt=" "<br>Ventral fin
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V, Y and X tails
An alternative to the fin-and-tailplane approach is provided by the V-tail and X-tail designs. Here, the tail surfaces are set at diagonal angles, with each surface contributing to both pitch and yaw. The control surfaces, sometimes called ruddervators, act differentially to provide yaw control (in place of the rudder) and act together to provide pitch control (in place of the elevator).
The configuration was first developed during World War II by Richard Vogt and George Haag at Blohm & Voss. The Skoda-Kauba SL6 tested the proposed control system in 1944 and, following several design proposals, an order was received for the Blohm & Voss P 215 just weeks before the war ended. The outboard tail reappeared on the Scaled Composites SpaceShipOne in 2003 and SpaceShipTwo in 2010.
Tailless aircraft
thumb|The [[de Havilland DH 108|DH108 Swallow had a tailless design.]]
A tailless aircraft (often tail-less) traditionally has all its horizontal control surfaces on its main wing surface. It has no horizontal stabiliser either tailplane or canard foreplane (nor does it have a second wing in tandem arrangement). A "tailless" type usually still has a vertical stabilising fin (vertical stabiliser) and control surface (rudder). However, NASA adopted the "tailless" description for the novel X-36 research aircraft which has a canard foreplane but no vertical fin.
See also
- S-duct
- Tail-sitter
- Trijet