A method for providing medical services to a patient, including: receiving a medical service request associated with a patient location; selecting an aircraft, located at an initial location, from a plurality of aircraft based on the patient location and the initial location; determining a flight plan for flying the aircraft to a region containing the patient location; at a sensor of the aircraft, sampling a first set of flight data; at a processor of the aircraft, autonomously controlling the aircraft to fly based on the flight plan and the set of flight data; selecting a landing location within the region; and landing the aircraft at the landing location, including: sampling a set of landing location data; determining a safety status of the landing location based on the set of landing location data; outputting a landing warning observable at the landing location; at the sensor, sampling a second set of flight data; and in response to determining the safety status and outputting the landing warning, autonomously controlling the aircraft to land at the landing location based on the second set of flight data.

A landing control method includes detecting whether a landing indication signal is received, and controlling an aircraft to automatically land in a pre-set landing mode if the landing indication signal is received. A takeoff control method comprises detecting whether a takeoff indication signal is received, and controlling an aircraft to automatically take off in a pre-set takeoff mode if the takeoff indication signal is received.

A landing control method includes detecting whether a landing indication signal is received, and controlling an aircraft to automatically land in a pre-set landing mode if the landing indication signal is received. A takeoff control method comprises detecting whether a takeoff indication signal is received, and controlling an aircraft to automatically take off in a pre-set takeoff mode if the takeoff indication signal is received.

A device for assisting in the landing of an aircraft in a flare phase comprising a control stick, a first unit for acquiring current flight parameters of the aircraft, a second unit for acquiring a current deflection angle of the control stick, a computation unit for computing a difference between the current deflection angle of the control stick and a target deflection angle of the control stick, and an acoustic emission unit configured to automatically emit a warning or guidance sound signal in the cockpit of the aircraft, according to the difference between the current deflection angle and the target deflection angle of the control stick.

A device for assisting in the landing of an aircraft in a flare phase comprising a control stick, a first unit for acquiring current flight parameters of the aircraft, a second unit for acquiring a current deflection angle of the control stick, a computation unit for computing a difference between the current deflection angle of the control stick and a target deflection angle of the control stick, and an acoustic emission unit configured to automatically emit a warning or guidance sound signal in the cockpit of the aircraft, according to the difference between the current deflection angle and the target deflection angle of the control stick.

A method and device for displaying a symbology for assisting the piloting of an aircraft during a landing phase. The display device allows a crew to anticipate or avoid emission of a runway overrun warning, able to be emitted by a piloting assistance unit. The display device includes a display unit to display a symbology, a module for determining characteristics of the runway and an end of runway margin, a module for determining a run distance necessary for the aircraft to attain a run speed, when the piloting assistance unit operates in a first mode, a transmission module configured for transmitting a set of signals making it possible for the display unit to display a symbol representative of the run distance, at least one symbols representative of the characteristics of the runway and a symbol representative of the end of runway margin.

Autoland systems and processes for landing an aircraft without pilot intervention are described. In implementations, the autoland system includes a memory operable to store one or more modules and at least one processor coupled to the memory. The processor is operable to execute the one or more modules to identify a plurality of potential destinations for an aircraft. The processor can also calculate a merit for each potential destination identified, select a destination based upon the merit; receive terrain data and/or obstacle data, the including terrain characteristic(s) and/or obstacle characteristic(s); and create a route from a current position of the aircraft to an approach fix associated with the destination, the route accounting for the terrain characteristic(s) and/or obstacle characteristic(s). The processor can also cause the aircraft to traverse the route, and cause the aircraft to land at the destination without requiring pilot intervention.

One example aspect of the present disclosure relates to a method for assessing input. The method can include determining a state of the aerial vehicle. The method can include obtaining data indicative of an expected operator input based on the determined state. The method can include obtaining data indicative of an actual operator input. The method can include determining a state of operator behavior based on the expected operator input and the actual operator input. The method can include determining a control action for the aerial vehicle based on the determined state of the aerial vehicle and the determined state of the operator behavior. The method can include implementing the control action.

One example aspect of the present disclosure relates to a method for assessing input. The method can include determining a state of the aerial vehicle. The method can include obtaining data indicative of an expected operator input based on the determined state. The method can include obtaining data indicative of an actual operator input. The method can include determining a state of operator behavior based on the expected operator input and the actual operator input. The method can include determining a control action for the aerial vehicle based on the determined state of the aerial vehicle and the determined state of the operator behavior. The method can include implementing the control action.

Systems and methods according to one or more embodiments are provided for limiting elevator deflection commands to avoid the aft body of an aircraft from contacting the ground during a landing maneuver. In one example, a system includes a memory configured to store a plurality of executable instructions and a processor. The processor is configured to determine a descent profile and a current pitch profile. A pre-determined maximum pitch profile associated with the descent profile is used to compare to the current pitch profile. The comparison is used to compute an elevator deflection value that limits an elevator command signal in order to avoid a tail strike. Additional systems and methods are also provided.