Passenger discomfort-aware flight control system

What is claimed is: 1. A flight control system that is adapted for controlling movements of a rotary wing aircraft, comprising: sensors that are configured to generate sensor data based on captured motions of the rotary wing aircraft; motion actuators that are adapted for inducing a translational and/or a rotational movement of the rotary wing aircraft about at least one of a yaw axis, a roll axis, or a pitch axis of the rotary wing aircraft; and a passenger discomfort-aware control unit that is configured to receive the sensor data from the sensors and to generate, based on the sensor data, passenger discomfort-aware actuator control signals for controlling the motion actuators, wherein the passenger discomfort-aware actuator control signals are at least suitable for kinetosis reduction or for whole-body vibration reduction in passengers of the rotary-wing aircraft when being applied to the motion actuators; wherein the passenger discomfort-aware control unit generates the passenger discomfort-aware actuator control signals based on a linear feedback function that minimizes a transfer from the sensor data to control signals that increase a difference of a passenger discomfort index from a reference value, the reference value being indicative of an absence of passenger discomfort; and the linear feedback function is determined with a feedback controller that is adjusted based on an application of a predetermined filter signal in a passenger discomfort weighting filter, the predetermined filter signal being determined based on motion simulations of representative trajectories of the rotary wing aircraft with a motion simulator for flight control system design. 2. The flight control system of claim 1 , wherein the representative trajectories of the rotary wing aircraft comprise translational motions and rotational motions about the yaw, roll, and pitch axis. 3. The flight control system of claim 1 , wherein the predetermined filter signal adjusts a motion frequency in the feedback controller. 4. The flight control system of claim 1 , wherein the predetermined filter signal adjusts a motion pattern in the feedback controller. 5. The flight control system of claim 1 , wherein the motion actuators include a pitch control unit configured to control collective and cyclic pitch of rotor blades of the rotary wing aircraft for inducing a translational and/or a rotational movement of the rotary wing aircraft about at least one of the yaw axis, the roll axis, or the pitch axis. 6. The flight control system of claim 1 , wherein the motion actuators include at least one motion actuator configured to control a drive system of the rotary wing aircraft for inducing a translational and/or a rotational movement of the rotary wing aircraft about at least one of the yaw axis, the roll axis, or the pitch axis. 7. A method of operating a flight control system for a rotary wing aircraft, comprising: using sensors to generate sensor data based on captured motions of the rotary wing aircraft; using motion actuators to induce a translational and/or a rotational movement of the rotary wing aircraft about at least one of a yaw axis, a roll axis, or a pitch axis of the rotary wing aircraft; using a passenger discomfort-aware control unit to receive the sensor data from the sensors and to generate, based on the sensor data, passenger discomfort-aware actuator control signals for controlling the motion actuators, wherein the passenger discomfort-aware actuator control signals are at least suitable for kinetosis reduction or for whole-body vibration reduction in passengers of the rotary-wing aircraft when being applied to the motion actuators; and configuring the passenger discomfort-aware control unit before using the passenger discomfort-aware control unit in the flight control system; wherein configuring the passenger discomfort-aware control unit comprises: using a motion simulator to perform motion simulations of representative trajectories of the rotary wing aircraft; determining a filter signal based on the motion simulations; adjusting a feedback controller based on an application of the filter signal in a passenger discomfort weighting filter; and with the adjusted feedback controller, determining a linear feedback function that minimizes a transfer from the sensor data to control signals that increase a difference of a passenger discomfort index from a reference value, the reference value being indicative of an absence of passenger discomfort. 8. The method of claim 7 , wherein the representative trajectories of the rotary wing aircraft comprise translational motions and rotational motions around the yaw, roll, and pitch axes of the rotary wing aircraft. 9. The method of claim 7 , wherein adjusting the feedback controller further comprises: with the filter signal, adjusting a motion frequency in the feedback controller. 10. The method of claim 7 , wherein adjusting the feedback controller further comprises: with the filter signal adjusting a motion pattern in the feedback controller. 11. The method of claim 7 , wherein using motion actuators to induce a translational and/or a rotational movement of the rotary wing aircraft about at least one of a yaw axis, a roll axis, or a pitch axis includes using a pitch control unit configured to control collective and cyclic pitch of rotor blades of the rotary wing aircraft to inducing the translational and/or the rotational movement of the rotary wing aircraft about at least one of the yaw axis, the roll axis, or the pitch axis. 12. The method of claim 7 , wherein using motion actuators to induce a translational and/or a rotational movement of the rotary wing aircraft about at least one of a yaw axis, a roll axis, or a pitch axis includes using at least one motion actuator configured to control a drive system of the rotary wing aircraft to induce the translational and/or the rotational movement of the rotary wing aircraft about at least one of the yaw axis, the roll axis, or the pitch axis.