The present invention relates to methods of controlling the flight path of an aircraft to follow as closely as possible a predetermined four-dimensional flight path, such as when flying continuous descent approaches. A method of controlling an aircraft to follow a predetermined four-dimensional flig
The present invention relates to methods of controlling the flight path of an aircraft to follow as closely as possible a predetermined four-dimensional flight path, such as when flying continuous descent approaches. A method of controlling an aircraft to follow a predetermined four-dimensional flight path is provided that comprises monitoring an actual along-track position and an actual vertical position of the aircraft relative to corresponding desired positions on the predetermined flight path. Throttle commands are generated based on deviations of the actual vertical position of the aircraft from the desired vertical position. Elevator commands are generated based on the deviation of the actual along-track position from the desired along-track position and on the deviation of the actual vertical position from the desired vertical position.
대표청구항▼
1. A method of guiding an aircraft to follow a predetermined four-dimensional flight path, comprising: monitoring an actual along-track position and an actual vertical position of the aircraft relative to corresponding desired along-track and vertical positions on the predetermined flight path;gener
1. A method of guiding an aircraft to follow a predetermined four-dimensional flight path, comprising: monitoring an actual along-track position and an actual vertical position of the aircraft relative to corresponding desired along-track and vertical positions on the predetermined flight path;generating throttle commands based on deviations of the actual vertical position of the aircraft from the desired vertical position; andgenerating elevator commands based on an along-track position deviation of the actual along-track position from the desired along-track position, a vertical position deviation of the actual vertical position from the desired vertical position, and a ground speed deviation of the actual ground speed of the aircraft from the desired ground speed of the aircraft,wherein said generating elevator commands comprises:obtaining a current calibrated airspeed from flight data;converting said ground speed deviation to an equivalent calibrated airspeed deviation;modifying said current calibrated airspeed by an amount that is a function of said calibrated airspeed deviation to form a first calibrated airspeed command;modifying said first calibrated airspeed command by an amount that is a function of said along-track position deviation to form a second calibrated airspeed command;modifying said second calibrated airspeed command by an amount that is a function of said vertical position deviation to form a third calibrated airspeed command; andcommanding actuations of elevators in accordance with said third calibrated airspeed command. 2. The method of claim 1, further comprising generating throttle commands based on deviations of the actual vertical position of the aircraft from the desired vertical position when the actual vertical position differs from the desired vertical position by more than a threshold. 3. The method of claim 2, further comprising using the throttle commands to alter the throttle setting from a nominal value to an adjusted value. 4. The method of claim 3, wherein generating throttle commands and using the throttle commands to alter the throttle setting comprises: increasing the throttle setting from a nominal value to a higher value when the actual vertical position falls below the desired vertical position by a first threshold, anddecreasing the throttle setting from the nominal value to a lower value when the actual vertical position rises above the desired vertical position by a second threshold. 5. The method of claim 4, further comprising: after altering the throttle setting and while the throttle setting is at the altered higher or lower value, continuing to monitor the actual along-track position and the actual vertical position of the aircraft relative to the corresponding desired along-track and vertical positions on the predetermined flight path; and generating throttle commands and using the throttle commands to return the throttle setting to the nominal value once the actual vertical position of the aircraft corresponds to the desired vertical position. 6. The method of claim 1, further comprising generating throttle commands based on predictions of deviations of the actual vertical position of the aircraft from the desired vertical position. 7. The method of claim 6, further comprising repeatedly calculating a predicted deviation in vertical position by: calculating the current deviation of actual vertical position from the desired vertical position, calculating the rate of change of the deviation in vertical position, multiplying the rate of change by a prediction time span, and adding the so-multiplied rate of change to the current deviation in vertical position, thereby obtaining the predicted deviation in vertical position; and generating a throttle command based on the predicted deviation in vertical position. 8. The method as recited in claim 1, wherein said modifying said current calibrated airspeed by an amount that is a function of said calibrated airspeed deviation comprises multiplying said calibrated airspeed deviation by a first gain factor, said modifying said first calibrated airspeed command by an amount that is a function of said along-track position deviation comprises multiplying said along-track position deviation by a second gain factor, and said modifying said second calibrated airspeed command by an amount that is a function of said vertical position deviation comprises multiplying said vertical position deviation by a third gain factor. 9. The method as recited in claim 1, wherein said generating elevator commands further comprises checking whether said third calibrated airspeed command is within a range bounded by upper and lower limits, said commanding actuations of elevators in accordance with said third calibrated airspeed occurring only if said third calibrated airspeed command is within said range. 10. A flight control computer programmed to perform the following operations: monitoring an actual along-track position and an actual vertical position of the aircraft relative to corresponding desired positions on the predetermined flight path;generating throttle commands based on deviations of the actual vertical position of the aircraft from the desired vertical position; andgenerating elevator commands based on an along-track position deviation of the actual along-track position from the desired along-track position, a vertical position deviation of the actual vertical position from the desired vertical position, and a ground speed deviation of the actual ground speed of the aircraft from the desired ground speed of the aircraft,wherein said generating elevator commands comprises:obtaining a current calibrated airspeed from flight data;converting said ground speed deviation to an equivalent calibrated airspeed deviation;modifying said current calibrated airspeed by an amount that is a function of said calibrated airspeed deviation to form a first calibrated airspeed command;modifying said first calibrated airspeed command by an amount that is a function of said along-track position deviation to form a second calibrated airspeed command;modifying said second calibrated airspeed command by an amount that is a function of said vertical position deviation to form a third calibrated airspeed command; andcommanding actuations of elevators in accordance with said third calibrated airspeed command. 11. The flight control computer of claim 10, further programmed to send instructions for throttle commands based on deviations of the actual vertical position of the aircraft from the desired vertical position when the actual vertical position differs from the desired vertical position by more than a threshold. 12. The flight control computer of claim 10, wherein said modifying said current calibrated airspeed by an amount that is a function of said calibrated airspeed deviation comprises multiplying said calibrated airspeed deviation by a first gain factor, said modifying said first calibrated airspeed command by an amount that is a function of said along-track position deviation comprises multiplying said along-track position deviation by a second gain factor, and said modifying said second calibrated airspeed command by an amount that is a function of said vertical position deviation comprises multiplying said vertical position deviation by a third gain factor. 13. The flight control computer of claim 10, wherein said generating elevator commands further comprises checking whether said third calibrated airspeed command is within a range bounded by upper and lower limits, said commanding actuations of elevators in accordance with said third calibrated airspeed occurring only if said third calibrated airspeed command is within said range. 14. A computer-implemented method of guiding an aircraft to follow a predetermined four-dimensional flight path, comprising: monitoring an actual along-track position and an actual vertical position of the aircraft relative to corresponding desired along-track and vertical positions on the predetermined flight path;generating throttle commands based on deviations of the actual vertical position of the aircraft from the desired vertical position; andgenerating elevator commands based on an along-track position deviation of the actual along-track position from the desired along-track position, a vertical position deviation of the actual vertical position from the desired vertical position, and a ground speed deviation of the actual ground speed of the aircraft from the desired ground speed of the aircraft,wherein said generating elevator commands comprises:obtaining a current calibrated airspeed from flight data;converting said ground speed deviation to an equivalent calibrated airspeed deviation;modifying said current calibrated airspeed by an amount that is a function of said calibrated airspeed deviation to form a first calibrated airspeed command;modifying said first calibrated airspeed command by an amount that is a function of said along-track position deviation to form a second calibrated airspeed command;modifying said second calibrated airspeed command by an amount that is a function of said vertical position deviation to form a third calibrated airspeed command; andcommanding actuations of elevators in accordance with said third calibrated airspeed command. 15. The computer-implemented method of claim 14, further comprising generating throttle commands based on predictions of deviations of the actual vertical position of the aircraft from the desired vertical position. 16. The computer-implemented method as recited in claim 14, wherein said modifying said current calibrated airspeed by an amount that is a function of said calibrated airspeed deviation comprises multiplying said calibrated airspeed deviation by a first gain factor, said modifying said first calibrated airspeed command by an amount that is a function of said along-track position deviation comprises multiplying said along-track position deviation by a second gain factor, and said modifying said second calibrated airspeed command by an amount that is a function of said vertical position deviation comprises multiplying said vertical position deviation by a third gain factor. 17. The computer-implemented method as recited in claim 14, wherein said generating elevator commands further comprises checking whether said third calibrated airspeed command is within a range bounded by upper and lower limits, said commanding actuations of elevators in accordance with said third calibrated airspeed occurring only if said third calibrated airspeed command is within said range.
연구과제 타임라인
LOADING...
LOADING...
LOADING...
LOADING...
LOADING...
이 특허에 인용된 특허 (14)
Rumbo, Jim R.; Jackson, Michael R.; O'Laughlin, Brian E., Aircraft control system for reaching a waypoint at a required time of arrival.
Najmabadi Kioumars ; Evans Monte R. ; Coleman Edward E. ; Bleeg Robert J. ; Breuhaus Richard S. ; Anderson Dorr Marshall ; Nelson Timothy A., Aircraft pitch-axis stability and command augmentation.
Young, Shih-Yih; Jerome, Kristen M., Predictable and required time of arrival compliant optimized profile descents with four dimensional flight management system and related method.
※ AI-Helper는 부적절한 답변을 할 수 있습니다.