Balanced field takeoff

In

takeoff distance required (TODR) with one engine inoperative and the accelerate-stop distance are equal for the aircraft weight, engine thrust, aircraft configuration and runway condition.^[1] For a given aircraft weight, engine thrust, aircraft configuration, and runway condition, the shortest runway length that complies with safety regulations is the balanced field length.^[2]^[3]^[4]

The takeoff decision speed

V₁ is the fastest speed at which the pilot must take the first actions to reject the takeoff (e.g. reduce thrust, apply brakes, deploy speed brakes). At speeds below V₁ the aircraft can be brought to a halt before the end of the runway. At V₁ and above, the pilot should continue the takeoff even if an emergency is recognized. The speed will ensure the aircraft achieves the required height above the takeoff surface within the takeoff distance.^{[citation needed}

]

To achieve a balanced field takeoff, V₁ is selected so the take-off distance with one engine inoperative, and the accelerate-stop distance, are equal.

accelerate-stop distance to be no greater than the accelerate-stop distance available (ASDA).^[5]^[6]

On runways longer than the balanced field length for the aircraft weight the operator may be able to choose V₁ from a range of speeds if adequate information is supplied by the aircraft manufacturer. The slowest speed in this range will be determined by the Take Off Distance Available (TODA).[7] For a low V₁, if an engine fails just above V₁, the acceleration to V_R on one engine will take more distance. Whereas, if an engine fails before a low V₁, it will take less distance to stop, so the Accelerate Stop Distance Required (ASDR) is lower. By contrast, the fastest speed in this range will be determined by the Accelerate Stop Distance Available (ASDA).^[7] If an engine fails above a high V₁, it will take less distance to reach V_R, so Take Off Distance Required (TODR) is lower. Whereas, if an engine fails just below a high V₁, it will take more distance to stop, so the Accelerate Stop Distance Required is greater.^[8]

Alternatively, on runways longer than the balanced field length the pilot can use reduced thrust, resulting in the balanced field length again being equal to the runway length available.^{[citation needed]}

Factors affecting the balanced field length include:

the mass of the aircraft – higher mass results in slower acceleration and higher takeoff speed
engine thrust – affected by temperature and air pressure, but reduced thrust can also be deliberately selected by the pilot
density altitude – reduced air pressure or increased temperature increases minimum take off speed
aircraft configuration such as wing
flap
position
runway slope and runway wind component
runway conditions – a rough or soft field slows acceleration, a wet or icy field reduces braking

Technology

Calculation of the balanced field length traditionally involves relying on an expansion program model, where the various forces are evaluated as a function of speed, and step-wise integrated, using an estimate for V₁. The process is iterated with different values for the engine failure speed until the accelerate-stop and accelerate-go distances are equal. This process suffers from the inherently slow and repetitive approach, which is also subject to round-off errors if the speed increment between the steps is not carefully selected, which could cause some issues in first principle aircraft performance models provided to airlines for day-to-day operations. Alternate approaches using a more mathematically complex but inherently more accurate and faster algebraic integration method have however been developed.^[9]

Landing and Takeoff Performance Monitoring Systems^[10]^[11]^[12]^[13] are devices aimed at providing the pilot with information on the validity of the performance computation, and averting runway overruns that occur in situations not adequately addressed by the takeoff V-speeds concept.^{[clarification needed]}

References

^ ^a ^b V-speeds and Takeoff Performance #265,18,Balanced Field Takeoff (Balanced), archived from the original (ppt) on 27 February 2012, retrieved 8 July 2013
^ Balanced field length, retrieved 22 September 2009
^ Balanced field length, archived from the original on 21 April 2021, retrieved 22 September 2009
ISBN 0-07-116010-8

^ "Code of Federal Regulations. Title 14 Chapter I Subchapter C Part 25 Subpart B Performance, Section 25.113 Takeoff distance and takeoff run". ecfr.gov. Federal Register. Retrieved 12 October 2022.

^ "Code of Federal Regulations. Title 14 Chapter I Subchapter C Part 25 Subpart B Performance, Section 25.109 Accelerate-stop distance". ecfr.gov. Federal Register. Retrieved 12 October 2022.

^
ISBN 978-0-470-69305-6
. Retrieved 12 October 2022.

ISBN 979-8-5062-2969-8
. Retrieved 13 October 2022.

doi:10.4271/2013-01-2324
.

^ Chapter 6-5 Airborne Trailblazer Archived 29 September 2006 at the Wayback Machine

^ Pinder, S.D., Takeoff Performance Monitoring in Far-Northern Regions: An Application of the Global Positioning System, doctoral thesis, University of Saskatchewan, 2002

^ Srivatsan, R., Takeoff Performance Monitoring, doctoral thesis, University of Kansas, 1986

^ Khatwa, R., The Development of a Takeoff Performance Monitor, doctoral thesis, University of Bristol, 1991

External links

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Retrieved from "https://en.wikipedia.org/w/index.php?title=Balanced_field_takeoff&oldid=1270519253"

[selair-1] V-speeds and Takeoff Performance #265,18,Balanced Field Takeoff (Balanced), archived from the original (ppt) on 27 February 2012, retrieved 8 July 2013

[2] Balanced field length, retrieved 22 September 2009

[3] Balanced field length, archived from the original on 21 April 2021, retrieved 22 September 2009

[JDA-4] ISBN 0-07-116010-8

[CFR_25.113-5] "Code of Federal Regulations. Title 14 Chapter I Subchapter C Part 25 Subpart B Performance, Section 25.113 Takeoff distance and takeoff run". ecfr.gov. Federal Register. Retrieved 12 October 2022.

[CFR_25.109-6] "Code of Federal Regulations. Title 14 Chapter I Subchapter C Part 25 Subpart B Performance, Section 25.109 Accelerate-stop distance". ecfr.gov. Federal Register. Retrieved 12 October 2022.

[Swatton-7] 
ISBN 978-0-470-69305-6
. Retrieved 12 October 2022.

[Croucher-8] ISBN 979-8-5062-2969-8
. Retrieved 13 October 2022.

[9] :10.4271/2013-01-2324
.

[10] Chapter 6-5 Airborne Trailblazer Archived 29 September 2006 at the Wayback Machine

[11] Pinder, S.D., Takeoff Performance Monitoring in Far-Northern Regions: An Application of the Global Positioning System, doctoral thesis, University of Saskatchewan, 2002

[12] Srivatsan, R., Takeoff Performance Monitoring, doctoral thesis, University of Kansas, 1986

[13] Khatwa, R., The Development of a Takeoff Performance Monitor, doctoral thesis, University of Bristol, 1991

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Technology

See also

References

External links