The invention relates to a force application device for a control stick of an aircraft, said control stick comprising a control lever that is connected to at least one motor comprising a drive shaft that can be rotated about an axis, the force application device comprising: a first pin connected to the shaft, a housing, an electromagnet, a movable actuator comprising a magnetic material, a coupling device comprising an input gear connected to the housing and an output gear comprising a second pin, and means for clamping the first pin and the second pin which comprise a first tooth and a second tooth, said device having an operating configuration in which the electromagnet is active and the output gear is positioned at a distance from the input gear, and a blocking configuration in which the electromagnet is inactive and the gears are meshed.

Systems and methods for controlling a fixed-wing aircraft during flight are disclosed. The aircraft comprises first and second flight control surfaces of different types. The method comprises determining that a pilot command of the first flight control surface will excite a structural flexible mode of the aircraft and then executing the pilot command of the first flight control surface in conjunction with a command of the second flight control surface to mitigate the effect of the excitation of the structural flexible mode of the aircraft.

In one embodiment, a flight control system is configured to receive one or more pilot inputs intended to effect a particular control outcome for the aircraft, receive one or more current flight parameters of the aircraft, determine whether or not the aircraft is near or in a stall, and if it is determined that the aircraft is near or in a stall, automatically control the aircraft's flight control surfaces in an oscillatory manner that increases the sensitivity of the flight control surfaces and achieves the pilot's intended control outcome.

The invention relates to a force application device for an aircraft control stick comprising: —a casing (24), —an electromagnet (22) mounted on the casing (24), —an actuator (30) mounted on the shaft (13), the actuator (30) being mobile in translation in relation to the shaft (13) along the axis (A), the actuator (30) comprising a magnetic material, and —a coupling device comprising an input gear (40) that is mounted so as to be stationary in relation to the casing (24) and an output gear (50) connected to the actuator (30) by means of an attachment part (60), the attachment part (60) being configured so as to allow a limited angular displacement between the output gear (50) and the shaft (13) around the axis (A) and to allow the actuator (30) of the output gear (50) to translate along the axis (A).

The invention relates to a force application device for a control stick of an aircraft, said stick comprising a control lever that is connected to a motor comprising a drive shaft, said device having: a first pin connected to the drive shaft, a housing, a second pin secured to the housing, an electromagnet secured in relation to the housing, a movable actuator which comprises a magnetic material such that said actuator can be displaced depending on a supply of current of the electromagnet, and means for clamping the first pin and the second pin which comprise a first tooth and a second tooth, said device having an operating configuration in which the electromagnet is active and the actuator separates the teeth away from the first pin and the second pin, and a blocking configuration in which the electromagnet is inactive, with the first tooth and the second tooth coming into contact with the first pin and the second pin.

The invention provides a device comprising a control lever associated with a body carrying a first plate connected to the body, a second plate connected to the first plate with the control lever being connected to the second plate, a first transmission shaft pivotally mounted relative to the body, a first connection mechanism connecting the control lever to the first transmission shaft in such a manner that pivoting of the control lever about the first axis causes the first shaft to pivot about the fourth axis, a second transmission shaft pivotally mounted relative to the body, a second connection mechanism connecting the control lever to the second transmission shaft in such a manner that pivoting of the control lever about the second axis causes the second shaft to pivot about the sixth axis, and a platform connected to the body, the second connection mechanism being pivotally mounted on the platform and being pivotally mounted on the control lever.

A personal aircraft assembly includes a carriage that can have a driver positioned therein. A plurality of jet packs is each coupled to the carriage for producing thrust to facilitate low altitude flight. Each of the jet packs has an exhaust nozzle pivotally coupled thereto and the exhaust nozzle on each of the jet packs is directed downwardly for lifting the carriage. A fuel tank is coupled to the carriage and the fuel tank is in fluid communication with each of the jet packs to supply fuel to the jet packs. A control stick is movably coupled to the carriage and the control stick is in communication with each of the jet packs. The control stick communicates control commands to the jet packs to facilitate flight control for the driver.

A VTOL inceptor arrangement is handled by a single pilot and consists of or comprises a first inceptor and a second inceptor. The first inceptor is capable of controlling at least one axis of movement and the second inceptor is capable of controlling at least three axes of movement. The first inceptor is configured to be operated by a first hand of the pilot, and the second inceptor is configured to be operated by a second hand of the pilot different from the first hand. These two hand-operated inceptors enable use of reliable operation based on stick motion (i.e., the pilot's respective hands each grasp a respective inceptor) instead of relying on movement of switches, knobs or the like—which may not allow precision control under vibration or turbulent environments or conditions.

In an embodiment, a method of indicating flight modes of a rotorcraft includes: detecting a change in flight mode of the rotorcraft from a previous flight mode to an active flight mode, the active flight mode and the previous flight mode each being from one of a first subset or a second subset of a plurality of flight modes; determining whether the active flight mode and the previous flight mode are from different subsets of the plurality of flight modes; and updating one or more flight mode indicators on an instrument panel of the rotorcraft in response to the active flight mode and the previous flight mode being from different subsets of the plurality of flight modes.

In an embodiment, a method includes: obtaining a first signal from a first sensor of a rotorcraft, the first signal indicating measured angular velocity around a first axis of the rotorcraft; filtering the first signal with a lag compensator to estimate angular position around the first axis of the rotorcraft; and adjusting flight control devices of the rotorcraft according to the estimated angular position and the measured angular velocity around the first axis of the rotorcraft, thereby changing flight characteristics of the rotorcraft around the first axis of the rotorcraft.