Method and device for vertically guiding an aircraft during an approach of a runway along a lateral approach trajectory
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
B64D-045/04
G05D-001/06
B64C-013/18
G01C-023/00
G05D-001/04
출원번호
US-0586433
(2014-12-30)
등록번호
US-9561868
(2017-02-07)
우선권정보
FR-14 50026 (2014-01-03)
발명자
/ 주소
Bourret, Thierry
Ahualle Horimoto, Kenji
출원인 / 주소
AIRBUS OPERATIONS (S.A.S.)
대리인 / 주소
Jenkins, Wilson, Taylor & Hunt, P.A.
인용정보
피인용 횟수 :
1인용 특허 :
52
초록▼
A method and device including a unit to extract a linear terrain profile stored in memory, a terrain height for a current distance of the aircraft, a unit for determining a current height of the aircraft with respect to the terrain, using at least one measurement taken by a radar altimeter, a unit f
A method and device including a unit to extract a linear terrain profile stored in memory, a terrain height for a current distance of the aircraft, a unit for determining a current height of the aircraft with respect to the terrain, using at least one measurement taken by a radar altimeter, a unit for computing a first current altitude of the aircraft, using the terrain height and the current height, a unit for computing a second current altitude of the aircraft, corresponding to an altitude on an approach profile of the current position of the aircraft and a unit for computing the difference between the first and second current altitudes, the difference being transmitted to a guidance unit to vertically guide the aircraft.
대표청구항▼
1. A method of vertical guidance of an aircraft during an approach to a landing runway along a lateral approach trajectory, the method comprising successive steps of automatically and repeatedly: a) determining a current distance corresponding to a distance in a lateral plane along the lateral appro
1. A method of vertical guidance of an aircraft during an approach to a landing runway along a lateral approach trajectory, the method comprising successive steps of automatically and repeatedly: a) determining a current distance corresponding to a distance in a lateral plane along the lateral approach trajectory, between a current position of the aircraft and a threshold of the landing runway;b) extracting from a linear terrain profile stored in a database and defined along the lateral approach trajectory, a terrain height for the current distance, the terrain height being defined with respect to a level of the threshold of the landing runway;c) determining a current height of the aircraft with respect to the terrain height, using at least one measurement taken by at least one on-board radar altimeter at the current position;d) computing a first current altitude of the aircraft, with respect to the level of the threshold of the landing runway, using the current height of the aircraft and the terrain height;e) computing an approach profile corresponding to a half-line having a predetermined angle with respect to a horizontal and comprising an endpoint that is situated on the landing runway at a predetermined distance defined by a difference in distance between the endpoint and the threshold of the landing runway, wherein the half-line comprises a slope corresponding to a change in height above the runway divided by a change in distance along the horizontal at a declination rate determined by the predetermined angle;f) computing a second current altitude of the aircraft, with respect to the level of the threshold of the landing runway, corresponding to an altitude on the approach profile for the current distance;g) computing a difference between the first current altitude and the second current altitude; andh) using the difference to vertically guide the aircraft. 2. The method of claim 1, wherein step a) comprises sub-steps comprising: determining the current position of the aircraft, using measurements taken by an on-board receiver forming part of a satellite positioning system; andcomputing the current distance, using the current position and a stored predetermined position of the threshold of the landing runway. 3. The method of claim 1, wherein step c) comprises determining the current height to be the current height measured by the at least one on-board radar altimeter. 4. The method of claim 1, wherein step c) comprises determining the current height to be a hybrid height, by implementing successive sub-steps comprising: c1) filtering, using a low-pass filter, a measurement taken by the radar altimeter to obtain a first value;c2) measuring the vertical speed of the aircraft, in integrating the vertical speed, and in filtering the vertical speed, using a high-pass filter, to obtain a second value; andc3) summing the first value and the second value to obtain the hybrid height. 5. The method of claim 1, wherein step d) comprises summing the current height and the terrain height to compute the first current altitude. 6. The method of claim 1, wherein a position correction on the aircraft, between an on-board receiver forming part of a satellite positioning system and the at least one on-board radar altimeter, is implemented repeatedly using a current angle of inclination and relative positions of antennas of the aircraft, referencing measurements taken by the on-board receiver and measurements taken by the at least one on-board radar altimeter with respect to a same reference point on the aircraft. 7. The method of claim 1, wherein step f) comprises computing, as the second current altitude, the altitude on the approach profile at a lateral distance from the threshold of the landing runway corresponding to the current distance. 8. The method of claim 1, wherein an alert signal is emitted in the cockpit of the aircraft when an accuracy of the current position of the aircraft is below a predetermined accuracy threshold, the current position and the accuracy being determined using an on-board receiver forming part of a satellite positioning system. 9. The method of claim 1, further comprising estimating a bias in the current distance of the aircraft and in correcting the current distance by the bias. 10. The method of claim 9, wherein estimating the bias comprises sub-steps comprising, during the approach: α) estimating a profile of a terrain overflown, using measurements taken; andβ) correlating the profile of the terrain overflown, with the linear terrain profile stored in memory in such a way as to deduce the bias therefrom, the steps α) and β) being repeated iteratively, taking into account at each iteration the bias deduced in a preceding iteration. 11. The method of claim 1, wherein the difference between the first current altitude and the second current altitude is expressed in a form of an angular deviation between two half-lines. 12. The method of claim 1, further comprising displaying the difference on a screen of a cockpit. 13. A device for vertical guidance of an aircraft during an approach to a landing runway along a lateral approach trajectory, the vertical guidance device comprising at least the following on-board units: a tracking unit comprising at least one receiver for determining a current position of the aircraft; at least one radar altimeter and at least one guidance unit; and the device further comprising on-board units comprising: a database storing a linear terrain profile defined along the lateral approach trajectory;a first computing unit configured to determine a current distance corresponding to a distance in a lateral plane along the lateral approach trajectory, between the current position of the aircraft and a threshold of the landing runway;a second computing unit configured to extract from the linear terrain profile stored in the database, a terrain height for the current distance, determined by the first computing unit, the terrain height defined with respect to a level of the threshold of the landing runway;a third computing unit configured to determine a current height of the aircraft with respect to the terrain height, using at least one measurement taken by the radar altimeter at the current position;a fourth computing unit configured to compute a first current altitude of the aircraft, with respect to the level of the threshold of the landing runway, using the terrain height and the current height of the aircraft, received from the second and third computing units respectively;a fifth computing unit configured to compute an approach profile corresponding to a half-line having a predetermined angle with respect to a horizontal and comprising an endpoint that is situated on the landing runway at a predetermined distance defined by a difference in distance between the endpoint and the threshold of the landing runway and a second current altitude of the aircraft, with respect to the level of the threshold of the landing runway, corresponding to an altitude on the approach profile of the current position; anda sixth computing unit configured to compute a difference between the first current altitude and the second current altitude, received from the fourth and fifth computing units, respectively, the difference being transmitted to the guidance unit that uses the difference to vertically guide the aircraft;wherein each of the first computing unit, the second computing unit, the third computing unit, the fourth computing unit, the fifth computing unit, and the sixth computing unit comprises a hardware processor; andwherein the half-line comprises a slope corresponding to a change in height above the runway divided by a change in distance along the horizontal at a declination rate determined by the predetermined angle. 14. The device of claim 13, wherein the guidance unit comprises at least one of: an automatic pilot system and a flight director. 15. An aircraft comprising: a vertical guidance device configured for vertical guidance of the aircraft during an approach to a landing runway along a lateral approach trajectory, the vertical guidance device comprising at least the following on-board units: a tracking unit comprising at least one receiver for determining a current position of the aircraft; at least one radar altimeter and at least one guidance unit; andthe device further comprising on-board units comprising: a database storing a linear terrain profile defined along the lateral approach trajectory;a first computing unit configured to determine a current distance corresponding to a distance in a lateral plane along the lateral approach trajectory, between the current position of the aircraft and a threshold of the landing runway;a second computing unit configured to extract from the linear terrain profile stored in the database, a terrain height for the current distance, determined by the first computing unit, the terrain height defined with respect to a level of the threshold of the landing runway;a third computing unit configured to determine a current height of the aircraft with respect to the terrain height, using at least one measurement taken by the radar altimeter at the current position;a fourth computing unit configured to compute a first current altitude of the aircraft, with respect to the level of the threshold of the landing runway, using the terrain height and the current height of the aircraft, received from the second and third computing units respectively;a fifth computing unit configured to compute an approach profile corresponding to a half-line having a predetermined angle with respect to a horizontal and comprising an endpoint that is situated on the landing runway at a predetermined distance defined by a difference in distance between the endpoint and the threshold of the landing runway and a second current altitude of the aircraft, with respect to the level of the threshold of the landing runway, corresponding to an altitude on the approach profile of the current position; anda sixth computing unit configured to compute a difference between the first current altitude and the second current altitude, received from the fourth and fifth computing units, respectively, the difference being transmitted to the guidance unit that uses the difference to vertically guide the aircraft;wherein each of the first computing unit, the second computing unit, the third computing unit, the fourth computing unit, the fifth computing unit, and the sixth computing unit comprises a hardware processor; andwherein the half-line comprises a slope corresponding to a change in height above the runway divided by a change in distance along the horizontal at a declination rate determined by the predetermined angle.
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