Aircraft approach category

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An aircraft approach category is a grouping which differentiates aircraft based on the speed at which the aircraft approaches a runway for landing.

Contents

They are used to determine airspace, obstacle clearance and visibility requirements for instrument approaches. [1] :II-5-1-3

Definition

The International Civil Aviation Organization (ICAO) classifies aircraft by their indicated airspeed at runway threshold (Vat, [1] :II-5-1-3 also known as approach speed or VREF).

The categories are as follows: [1] :II-5-1-3

Helicopters may use Category A minima on instrument procedures designed for aeroplanes, or may use specific procedures designed for helicopters. [1] :II-5-1-4

Threshold speed is calculated as 1.3 times stall speed Vs0 or 1.23 times stall speed Vs1g in the landing configuration at maximum certificated landing mass. [1] :Table II-5-1-2 Aircraft approach categories do not change during day-to-day operation. To change an aircraft's category, an aircraft must be re-certified with a different maximum landing mass. [1] :II-5-1-3 Pilots may not use a lower category than the one certified, but may choose to use a higher category for higher speed approaches. [2]

The maximum permitted speed for visual manoeuvring is significantly higher than the threshold speed. Additional speed ranges are specified for other segments of the approach. [1] :Table II-5-1-2

Approach plates generally include visibility requirements up to category D. [1] :II-5-1-3 While ICAO specify a top speed of 391 km/h for Category E, there exist no aircraft with an approach speed above this.

United States of America

Approach category definitions in the United States of America are similar to those defined by ICAO. They are defined in terms of VREF of a given aircraft, or if VREF is not specified, 1.3 Vs0 at the maximum certificated landing weight. The values of VREF, VS0, and the maximum certificated landing weight are established for the aircraft by the certification authority of the country of registry. The United States does not give a top speed for Category E. [3]

Examples

Selected examples from FAA Circular 150/5300-13A - Airport Design: [4]

AircraftCodeApproach Speed
Piper PA-28R Cherokee Arrow A70 kn (130 km/h)
Douglas DC-3 A74 kn (137 km/h)
Cessna 210 Centurion A75 kn (139 km/h)
Douglas DC-4 B94 kn (174 km/h)
Douglas DC-6 B108 kn (200 km/h)
Fokker F27 Friendship B120 kn (220 km/h)
Boeing 707-320B C128 kn (237 km/h)
McDonnell Douglas DC-9-15 C132 kn (244 km/h)
Boeing 737-700 C130 kn (240 km/h)
Boeing 737-800 D142 kn (263 km/h)
Airbus A350-900 D145 kn (269 km/h)
Boeing 747-400 D157 kn (291 km/h)

The Northrop T-38 Talon is an example of an Approach Category E aircraft.

The Space Shuttle had a landing speed of about 346 km/h (187 kn). [5]

See also

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References

  1. 1 2 3 4 5 6 7 8 "ICAO Doc 8168: Procedures for Air Navigation Services: Aircraft Operations: Volume I − Flight Procedures. Sixth edition, 2018" (PDF). ICAO. Retrieved 29 January 2023.
  2. https://nbaa.org/aircraft-operations/airspace/aim-revision-clarifies-approach-category-and-related-procedures/
  3. "14 CFR § 97.3 - Symbols and terms used in procedures" . Retrieved 29 January 2023.
  4. "AC 150/5300-13B - Airport Design - Change 1". www.faa.gov. Retrieved 1 December 2024.
  5. Galvez, Roberto. "The Space Shuttle and Its Operations" (PDF). p. 56. Retrieved 30 July 2024.