The system contains the active inceptor having mobility in a first direction. A feedback mechanism is in communication with the active inceptor. The mechanism provides a variable level of force to the active inceptor in the first direction. A programmable device communicates with the feedback mechan
The system contains the active inceptor having mobility in a first direction. A feedback mechanism is in communication with the active inceptor. The mechanism provides a variable level of force to the active inceptor in the first direction. A programmable device communicates with the feedback mechanism. The programmable device controls the level of force provided to the active inceptor from the feedback mechanism. The programmable device is capable of recognizing and distinguishing between regimes wherein the operator is physically engaging the inceptor (“hands-on” state) and when the operator is “hands-off” the inceptor. The programmable device limits the maximum rate of displacement of an active inceptor to a specified safe and effective value regardless of changes in forces applied by the variable force feel feedback mechanism. The limit on rate of change of active inceptor position is varied based on the recognized “hands-on” or “hands-off” state and the type of tactile cue to satisfy otherwise conflicting requirements for failure robustness and effective tactile cueing during highly dynamic operations.
대표청구항▼
1. A system comprising: an active inceptor configured to have mobility in at least a first direction;a feedback mechanism in communication with the active inceptor and in communication with a programmable device, wherein the programmable device controls: a level of force provided to the active incep
1. A system comprising: an active inceptor configured to have mobility in at least a first direction;a feedback mechanism in communication with the active inceptor and in communication with a programmable device, wherein the programmable device controls: a level of force provided to the active inceptor via the feedback mechanism; anda rate of change in the level of force (RoC) provided to the active inceptor via the feedback mechanism;a first sensor in communication with the active inceptor and with the programmable device, wherein the programmable device is configured to determine, based on the first sensor, a state of the active inceptor where the state of the active inceptor is one of a hands-on state or a hands-off state;wherein the programmable device is configured to provide a first RoC to the active inceptor via the feedback mechanism when the active inceptor is in the hands-on state;wherein the programmable device is configured to provide a second RoC to the active inceptor via the feedback mechanism when the active inceptor is in the hands-off state; andwherein the second RoC is less than the first RoC. 2. The system of claim 1, further comprising: a second sensor in communication with the active inceptor and the programmable device, wherein the second sensor detects a position of the active inceptor relative to the first direction; anda memory in communication with the programmable device, wherein the memory stores at least one tactile-cue position of the active inceptor, wherein the programmable device determines from information communicated by the second sensor and the memory whether the position of the active inceptor is one of the stored tactile-cue positions. 3. The system of claim 2, wherein the RoC provided by the programmable device is variable, whereby the RoC is a third RoC if the programmable device determines, from the information communicated by the second sensor and the memory, that the position of the active inceptor is at least proximate to one of the stored tactile-cue positions and a fourth RoC if the programmable device determines, from the information communicated by the second sensor and the memory, that the position of the active inceptor is not proximate to at least one of the stored tactile-cue positions; and wherein the programmable device is configured to set the third RoC and the fourth RoC to be less than the first RoC when the active inceptor is in the hands-off state. 4. The system of claim 3, wherein the memory further stores a plurality of tactile-cue positions of varying significance and wherein, if the programmable device determines the position of the active inceptor is at least proximate to one of the stored tactile-cue positions, the RoC is varied respective of the significance of the tactile-cue position. 5. The system of claim 1, wherein in the hands-off state, movement of the active inceptor is limited to allow a pilot response to a failure from an erroneous signal received from a load sensor. 6. The system of claim 1, wherein in the hands-on state, the active inceptor is moveable rapidly in response to an aggressive pilot input or a rapid change in a flight condition. 7. A method for rate limiting force feedback on an active inceptor having mobility in a first direction, the method comprising: controlling the active inceptor using a feedback mechanism and a programmable device, wherein the programmable device is configured to control: a level of force at the active inceptor via a first signal to the feedback mechanism; anda rate of change in the level of force (RoC) at the active inceptor via a third signal to the feedback mechanism;determining, based on a first sensor, a state of the active inceptor where the state of the active inceptor is one of a hands-on state or a hands-off state;controlling the active inceptor using the programmable device via the third signal when the active inceptor is in the hands-on state to a first maximum RoC;controlling the active inceptor using the programmable device via the third signal when the active inceptor is in the hands-off state to a second maximum RoC wherein the first maximum RoC is higher than the second maximum RoC; andcommunicating a second signal from the programmable device to the feedback mechanism, wherein the second signal changes the level of force provided to the active inceptor from the feedback mechanism in response to a change in one or more flight conditions. 8. The method of claim 7, further comprising: detecting a position of the active inceptor relative to the first direction;storing in a memory at least one tactile-cue position of the active inceptor; anddetermining from the detected position and tactile-cue position stored in the memory whether the detected position of the active inceptor is one of the stored tactile-cue positions. 9. The method of claim 8, wherein the RoC is variable, wherein limiting the RoC at which the level of force provided to the active inceptor is changed further comprises limiting the RoC to a third rate if the detected position of the active inceptor is at least proximate to one of the stored tactile-cue positions and limiting the RoC to a fourth rate if the detected position of the active inceptor is not at least proximate to one of the stored tactile-cue positions; and wherein the third rate and the fourth rate are less than the first RoC when the active inceptor is in the hands-off state. 10. The method of claim 9, further comprising storing a plurality of tactile-cue positions in memory and assigning each of the tactile-cue positions a varying level of significance, wherein if the detected position of the active inceptor is one of the stored tactile-cue positions, the RoC is varied respective of the level of significance of the tactile-cue position. 11. The method of claim 7, wherein in the hands-off state movement of the active inceptor is limited to allow a pilot response to a failure from an erroneous signal received from a load sensor. 12. The method of claim 7, wherein in the hands-on state, the active inceptor is moveable rapidly in response to an aggressive pilot input or a rapid change in a flight condition. 13. A method for rate limiting an active inceptor, the method comprising: controlling the active inceptor using a feedback mechanism and a programmable device, wherein the programmable device controls a level of force and a rate of change in the level of force (RoC) provided to the active inceptor via the feedback mechanism;determining, based on a first sensor, a state of the active inceptor where the state of the active inceptor is one of a hands-on state or a hands-off state;controlling the active inceptor via the programmable device and via the feedback mechanism to a first RoC when the active inceptor is in the hands-on state;controlling the active inceptor via the programmable device and via the feedback mechanism to a second RoC when the active inceptor is in the hands-off state, wherein the second RoC is less than the first RoC; andlimiting motion of the active inceptor based on the RoC. 14. The method of claim 13, further comprising: detecting a position of the active inceptor;storing in a memory at least one tactile-cue position of the active inceptor; anddetermining from the detected position and tactile-cue position stored in the memory whether the detected position of the active inceptor is one of the stored tactile-cue positions. 15. The method of claim 14, wherein the RoC is variable, wherein setting the RoC further comprises setting the RoC to a third rate if the detected position of the active inceptor is one of the stored tactile-cue positions and setting the rate to a fourth rate if the detected position of the active inceptor is not one of the stored tactile-cue positions wherein the third rate and the fourth rate are less than the first RoC when the active inceptor is in the hands-off state. 16. The method of claim 15, further comprising storing a plurality of tactile-cue positions in memory and assigning each of the tactile-cue positions a varying level of significance, wherein if the detected position of the active inceptor is at least proximate to one of the stored tactile-cue positions, the RoC is varied respective of the level of significance of the tactile-cue position. 17. The method of claim 13, wherein in the hands-off state, movement of the active inceptor is limited to allow a pilot response to a failure from an erroneous signal received from a load sensor. 18. The method of claim 13, wherein in the hands-on state, the active inceptor is movable rapidly in response to an aggressive pilot input or a rapid change in a flight condition.
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이 특허에 인용된 특허 (12)
Tessier, Claude; Martineau, Jonathan, Apparatus and method for controlling a force-activated controller.
Ferranti Michael J. (Naugatuck CT) Novis Ari M. (Rocky Hill CT) Durno Ronald A. (Trumbull CT), Programmable, linear collective control system for a helicopter.
Gregory William W. (St. Petersburg FL) Lance Wayne E. (Largo FL) Hegg Jeffrey W. (North Redington Beach FL), Variable servo loop compensation in an active hand controller.
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