IPC분류정보
국가/구분 |
United States(US) Patent
등록
|
국제특허분류(IPC7판) |
|
출원번호 |
US-0051803
(2008-03-19)
|
등록번호 |
US-8209072
(2012-06-26)
|
우선권정보 |
FR-07 01996 (2007-03-20) |
발명자
/ 주소 |
- Villaume, Fabrice
- Jacob, Armand
- Lignee, Robert
|
출원인 / 주소 |
|
대리인 / 주소 |
|
인용정보 |
피인용 횟수 :
6 인용 특허 :
4 |
초록
A method and device to assist in the piloting of an aircraft in a landing phase may apply a maximum braking of the aircraft if there is a risk of longitudinal departure from a runway.
대표청구항
▼
1. A method to assist piloting an aircraft during a landing phase at an airport having a plurality of runways, the method comprising: a1) automatically determining, for each of the runways of the airport, the runway's orientation and coordinates of the runway's threshold;a2) repetitively computing,
1. A method to assist piloting an aircraft during a landing phase at an airport having a plurality of runways, the method comprising: a1) automatically determining, for each of the runways of the airport, the runway's orientation and coordinates of the runway's threshold;a2) repetitively computing, for each runway, the runway's threshold based on the coordinates and orientation determined for the runway;a3) automatically and repetitively checking whether a characteristic height, which depends on the current altitude of the aircraft and on the altitude of the airport, is located within a predetermined height-wise detection window, a3i) setting a Boolean value to 1 if the characteristic height is within the predetermined height-wise detection window, anda3ii) setting the Boolean value to 0 if the characteristic height is not within the predetermined height-wise detection window;a4) repetitively computing for each runway, only when the Boolean value is set to 1, an angular difference between the orientation of the runway and a straight line passing through the current position of the aircraft;a5) computing, for each runway, a cumulative average of all computed angular differences;a6) comparing all computed cumulative averages with all other computed cumulative averages;a7) selecting a runway whose cumulative average is lowest according to the comparisons;b) repetitively determining the current longitudinal position of the aircraft in a reference frame linked to the selected runway;c) upon the aircraft passing the computed threshold of the selected runway: c1) repetitively determining a longitudinal stopping position of the aircraft from the current longitudinal position, andc2) repetitively comparing the longitudinal stopping position to the length of the selected runway;d) applying maximum braking to the aircraft while the determined longitudinal stopping position is greater than the length of the selected runway, wherein:the angular difference is computed for any runway of index k, by taking into account an orientation θAMk which is computed from the following expressions: -ifsin(μAC-μTHRk)<0,θAMk=arccos(sin(λAC)-sin(λTHRk)·cos(ρAMk)sin(ρAMk)·cos(λTHRk))-otherwise,θAMk=2π-arccos(sin(λAC)-sin(λTHRk)·cos(ρAMk)sin(ρAMk)·cos(λTHRk))-ρAMk=2R·arcsinsin2(λTHRk-λAC2)+cos(λTHRk)·cos(λAC)·sin2(μTHRk-μAC2)λTHRk and μTHRk are the latitude and longitude coordinates of the threshold of the runway of index k;λAC and μAC are the current latitude and longitude coordinates of the aircraft; andR is the radius of Earth. 2. The method of claim 1, further comprising issuing an alarm during a period the longitudinal stopping position is greater than the length of the selected runway. 3. The method of claim 1, further comprising comparing the selected runway to a runway manually determined by an operator so as to confirm a suitable runway for landing. 4. The method of claim 1, further comprising: presenting a variable symbol system, illustrating the longitudinal stopping position, on an airport map displayed by a display screen, whereinthe symbol system depends on the difference between the longitudinal stopping position and the length of the selected runway. 5. The method of claim 1, further comprising checking, intermediate between steps (a7) and (c), that the aircraft is landing on the selected runway. 6. The method of claim 1, further wherein the orientation of each runway is determined from latitude and longitude coordinates of the runway's threshold and latitude and longitude coordinates of the end of the runway. 7. The method of claim 1, further wherein: the characteristic height is determined from the median value of the following values: Hp-Ha, Hra and HO, where: Hp is the current baro-inertial altitude of the aircraft,Ha is the altitude of the airport,Hra is the current radio-altimetric altitude of the aircraft, andHO is a predetermined height value; andthe detection window is delimited by predetermined minimum and maximum height values. 8. A system to assist piloting an aircraft during a landing phase at an airport having a plurality of runways, the system comprising: a first determining section that automatically determines, for each of the runways of the airport, the runway's orientation and coordinates of the runway's threshold;a first computing section that repetitively computes, for each runway, the runway's threshold based on the coordinates and orientation determined for the runway;a checking section that automatically and repetitively checks whether a characteristic height, which depends on the current altitude of the aircraft and on the altitude of the airport, is located within a predetermined height-wise detection window, wherein the checking section: sets a Boolean value to 1 if the characteristic height is within the predetermined height-wise detection window, andsets the Boolean value to 0 if the characteristic height is not within the predetermined height-wise detection window;a second computing section that computes for each runway, only when the Boolean value is set to 1, an angular difference between the orientation of the runway and a straight line passing through the current position of the aircraft;a third computing section that computes, for each runway, a cumulative average of all computed angular differences;a first comparator that compares all computed cumulative averages with all other computed cumulative averages;a selector that selects a runway whose cumulative average is lowest according to the comparisons;a second determining section that repetitively determines the current longitudinal position of the aircraft in a reference frame linked to the selected runway;a fourth computing section that, upon the aircraft passing the computed threshold of the selected runway: repetitively determines a longitudinal stopping position of the aircraft from the current longitudinal position, andrepetitively compares the longitudinal stopping position to the length of the selected runway;a braking system that applies maximum braking to the aircraft while the determined longitudinal stopping position is greater than the length of the selected runway, wherein:the angular difference is computed for any runway of index k, by taking into account an orientation θAMk which is computed from the following expressions: -ifsin(μAC-μTHRk)<0,θAMK=arccos(sin(λAC)-sin(λTHRk)·cos(ρAMk)sin(ρAMk)·cos(λTHRk))-otherwise,θAMk=2π-arccos(sin(λAC)-sin(λTHRk)·cos(ρAMk)sin(ρAMk)·cos(λTHRk)),inwhich:ρAMk=2R·arcsinsin2(λTHRk-λAC2)+cos(λTHRk)·cos(λAC)·sin2(λTHRk-λAC2)λTHRk and μTHRk are the latitude and longitude coordinates of the threshold of the runway of index k;λAC and μAC are the current latitude and longitude coordinates of the aircraft; andR is the radius of Earth. 9. The system of claim 8, further comprising an alarm device that issues an alarm during a period the longitudinal stopping position is greater than the length of the selected runway. 10. An aircraft comprising the system of claim 8.
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