Alternative method to determine the air mass state of an aircraft and to validate and augment the primary method
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
G06F-007/00
G06F-017/00
B64C-019/00
B64C-013/50
G01P-005/16
G01P-013/02
B64D-043/00
출원번호
US-0282875
(2014-05-20)
등록번호
US-9731814
(2017-08-15)
발명자
/ 주소
McIntyre, Melville Duncan Walter
Houck, Andrew W.
Bridgewater, Russell T.
Freeman, Robert Erik
Salo, Paul
Wilson, Douglas L.
Moore, Jonathan K.
출원인 / 주소
THE BOEING COMPANY
대리인 / 주소
Patterson + Sheridan, LLP
인용정보
피인용 횟수 :
0인용 특허 :
14
초록▼
A method, apparatus, and computer program product for identifying air data for an aircraft. The lift for the aircraft is identified. The number of surface positions for the aircraft is identified. The angle of attack during flight of the aircraft is identified. A synthetic dynamic pressure is comput
A method, apparatus, and computer program product for identifying air data for an aircraft. The lift for the aircraft is identified. The number of surface positions for the aircraft is identified. The angle of attack during flight of the aircraft is identified. A synthetic dynamic pressure is computed from the lift, the number of surface positions, and the angle of attack.
대표청구항▼
1. A method for controlling an aircraft, comprising: continuously sensing first data directly from air using aircraft sensors, the aircraft sensors comprising a sideslip vane;continuously sensing second data comprising dynamic pressure, inertial data, control surface position data, and a gross weigh
1. A method for controlling an aircraft, comprising: continuously sensing first data directly from air using aircraft sensors, the aircraft sensors comprising a sideslip vane;continuously sensing second data comprising dynamic pressure, inertial data, control surface position data, and a gross weight of an aircraft;continuously determining a primary value of sideslip based on the first data;issuing, by one or more computer processors, control signals to at least one of control surfaces or engines for the aircraft based on the determined primary value of sideslipcontinuously determining a synthetic value of the sideslip based on the second data;continuously calculating a difference between the determined primary value of sideslip and the determined synthetic value of sideslip;upon the calculated difference exceeding a threshold amount, providing an alert;receiving, in response to the provided alert, a selection of the determined synthetic value of sideslip; andissuing, by the one or more computer processors, control signals to at least one of control surfaces or engines for the aircraft based on the selected determined synthetic value of sideslip. 2. A method for controlling an aircraft, comprising: continuously sensing first data with at least one first aircraft sensor;continuously sensing second data with at least one second aircraft sensor, wherein the at least one second aircraft sensor is of a different type than the at least one first aircraft sensor and that does not share a common cause fault with the at least one first aircraft sensor;continuously calculating a primary value of a parameter based on the first data;issuing, by one or more computer processors, control signals to at least one of control surfaces or engines for the aircraft based on the calculated primary value of the parameter;continuously calculating a synthetic value of the parameter based on the second data;continuously calculating a difference between the calculated primary value of the parameter and the calculated synthetic value of the parameter;upon the calculated difference exceeding a threshold amount, outputting an alert;receiving, in response to the output alert, a selection of the calculated synthetic value of the parameter; andissuing, by the one or more computer processors, control signals to at least one of control surfaces or engines for the aircraft based on the calculated synthetic value of the parameter in response to receiving the selection of the calculated synthetic value. 3. The method of claim 2, wherein the at least one first aircraft sensor includes at least one of: a pitot probe, a static pressure sensor, an angle of attack sensor, and a sideslip vane. 4. The method of claim 2, wherein the parameter comprises at least one of dynamic pressure, sideslip, static pressure, angle of attack, total pressure, and airspeed. 5. The method of claim 1, wherein the determining the synthetic value of the sideslip comprises determining a side force coefficient and determining the alternative value as the sideslip associated with the side force coefficient and the control surface position data. 6. The method of claim 5, wherein the determining the side force coefficient is based on the gross weight, a load factor of the inertial data, and the dynamic pressure. 7. The method of claim 2, wherein receiving the selection comprises receiving a selection of the primary value as the selected value upon determining that the primary value is valid, otherwise receiving a selection of the synthetic value upon determining that the primary value is not valid. 8. The method of claim 7, wherein the at least one first aircraft sensor comprises a plurality of first aircraft sensors each disposed at respective different locations on the aircraft, and wherein the determining that the primary value is valid comprises comparing respective instances of the first data received from respective ones of the plurality of first aircraft sensors. 9. The method of claim 2, wherein the second data comprises at least one of: inertial data, control surface position data, and a gross weight of an aircraft. 10. A method for controlling an aircraft, comprising: continuously sensing first data directly from air using aircraft sensors, the aircraft sensors comprising a pitot tube, and a static pressure sensor;continuously sensing second data comprising an angle of attack, inertial data, control surface position data, and a gross weight of an aircraft;continuously calculating a primary value of dynamic pressure based on the first data;issuing, by one or more computer processors, control signals to at least one of control surfaces or engines for the aircraft based on the calculated primary value of dynamic pressure;continuously calculating a synthetic value of the dynamic pressure based on the second data;continuously calculating a difference between the calculated primary value of dynamic pressure and the calculated synthetic value of dynamic pressure;upon the calculated difference exceeding a threshold amount, providing an alert;receiving, in response to the provided alert, a selection of the synthetic value; andissuing, by the one or more computer processors, control signals to at least one of control surfaces or engines for the aircraft based on the selected value. 11. The method of claim 1, wherein continuously determining a synthetic value of the sideslip based on the second data comprises: calculating a side force by multiplying the gross weight of the aircraft by a side load factor derived from the inertial data;calculating an area dynamic pressure by multiplying dynamic pressure from air data by an area of the wingcalculating a side force coefficient by dividing the side force by the area dynamic pressure;calculating a total side force coefficient by subtracting any change in side force coefficient caused by control surface positions from the calculated side force coefficient; andcalculating synthetic sideslip by dividing the total side force coefficient by a side force coefficient slope for the aircraft. 12. The method of claim 10, wherein the determining the synthetic value of the dynamic pressure is determined based on lift force, a lift coefficient, and a reference area of a wing of the aircraft. 13. A method for controlling an aircraft, comprising: continuously sensing first data directly from air using aircraft sensors, the aircraft sensors comprising a pitot tube and a static pressure sensor;continuously sensing second data comprising an angle of attack, inertial data, control surface position data, altitude information, and a gross weight of an aircraft;continuously determining a primary value of airspeed based on the first data;issuing, by one or more computer processors, control signals to at least one of control surface or engines for the aircraft based on the determined primary value of airspeed;continuously determining a synthetic value of the airspeed based on the second data;continuously calculating a difference between the determined primary value of airspeed and the determined synthetic value of airspeed;upon the calculated difference exceeding a threshold amount, providing an alert;receiving, in response to the provided alert, a selection of the determined synthetic value of airspeed; andissuing, by the one or more computer processors, control signals to at least one of control surfaces or engines for the aircraft based on the selected determined synthetic value of airspeed. 14. The method of claim 13, wherein the determining the synthetic value of the airspeed is determined based on an isentropic compressible flow relationship utilizing synthetic dynamic pressure and a static pressure. 15. The method of claim 14, wherein the determining the synthetic value of the airspeed comprises determining synthetic dynamic pressure based on a lift force, a lift coefficient, and a reference area of a wing of the aircraft. 16. The method of claim 13, wherein the selecting includes comparing the primary value of airspeed to the synthetic value of airspeed. 17. The method of claim 13, further including displaying the synthetic value within a cockpit upon selecting the synthetic value as the selected value. 18. A method for controlling an aircraft, comprising: continuously sensing first data of an angle of attack using an angle of attack sensor;continuously sensing second data comprising inertial data, dynamic pressure, control surface position data, and a gross weight of an aircraft;continuously calculating a primary value of the angle of attack based on the first data;issuing, by one or more computer processors, control signals to at least one of control surfaces or engines for the aircraft based on the calculated primary value of the angle of attack;continuously calculating a synthetic value of the angle of attack based on the second data;continuously calculating a difference between the primary value of the angle of attack and the synthetic value of the angle of attack;upon the calculated difference exceeding a threshold amount, providing an alert;receiving, in response to the provided alert, a selection of the calculated synthetic value of the angle of attack; andissuing, by the one or more computer processors, control signals to at least one of control surfaces or engines for the aircraft based on the selected calculated synthetic value of angle of attack. 19. The method of claim 13, wherein continuously determining the synthetic value of the airspeed based on the second data comprises: calculating lift force by multiplying the gross weight by a load factor derived from the inertial data;calculating a lift coefficient by multiplying the angle of attack by a slope of a lift coefficient for the wing of the aircraft and then adding the lift coefficient at a zero angle of attack for the wing and any change in lift coefficient caused by control surface positions;calculating an area lift coefficient by multiplying the calculated lift coefficient by an area of the wing;calculating a synthetic value of dynamic pressure by dividing the calculated lift force by the calculated area lift coefficient;calculating a static air pressure based on the altitude information and a standard pressure lapse rate curve;calculating a synthetic Mach number based on the calculated synthetic value of dynamic pressure and the calculated static air pressure;calculating a total air pressure based on the static pressure and Mach number;calculating an impact pressure by subtracting the calculated static air pressure from the calculated total air pressure; andcalculating the synthetic value of the air speed based on the speed of sound at sea level in standard atmospheric conditions, the static air pressure at sea level in standard atmospheric conditions, and the calculated impact pressure. 20. The method of claim 18, wherein the determining the synthetic value of the angle of attack comprises determining a coefficient of lift and determining the alternative value as the angle of attack associated with the coefficient of lift and the control surface position data. 21. The method of claim 20, wherein the determining the coefficient of lift is based on a calculated gross weight, a load factor of the inertial data, the dynamic pressure, and a reference area of a wing of the aircraft. 22. The method of claim 21, wherein the calculated gross weight is based on the gross weight, an inertial angle of attack and a feedback loop of the synthetic value. 23. The method of claim 18, wherein calculating the synthetic value of the angle of attack based on the second data comprises: calculating a pitch difference by subtracting flight path angle from pitch attitude angle, wherein the inertial data comprises the flight path angle and the pitch attitude angle;calculating inertial angle of attack by dividing the calculated pitch difference by a cosine of the roll attitude, wherein the inertial data comprises the roll angle;calculating an angle of attack difference by subtracting a previously calculated synthetic angle of attack from a feedback loop from the calculated inertial angle of attack;calculating a rate of change of gross weight by multiplying the angle of attack difference by a gain value;calculating a current gross weight for the aircraft by limiting the rate of change of gross weight to be within a range of rates of change of gross weight and integrating the limited rate of change of gross weight, using a starting gross weight of the aircraft, wherein the gross weight of the aircraft of the second data comprises the starting gross weight;calculating a lift force by multiplying the calculated current gross weight by a load factor derived from the inertial data;calculating an area dynamic pressure by multiplying dynamic pressure from air data by an area of the wing;calculating a lift coefficient by dividing the lift force by the area dynamic pressure;subtracting a total lift coefficient by substracting the lift coefficient at a zero angle of attack for the wing and any change in lift coefficient caused by control surface positions from the calculated lift coefficient; andcalculating synthetic angle of attack by dividing the total lift coefficient a lift coefficient slope for the aircraft. 24. The method of claim 10, wherein continuously calculating the synthetic value of the dynamic pressure based on the second data comprises: calculating lift force by multiplying the gross weight by a load factor derived from the inertial data;calculating a lift coefficient by multiplying the angle of attack by a slope of a lift coefficient for the wing of the aircraft and then adding the lift coefficient at a zero angle of attack for the wing and any change in lift coefficient caused by control surface positions;calculating an area lift coefficient by multiplying the calculated lift coefficient by an area of the wing; andcalculating the synthetic value of the dynamic pressure by dividing the calculated lift force by the calculated area lift coefficient.
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