An aircraft includes an autopilot system including one or more processors. The one or more processors are configured to, in response to selection of an autopilot activation button during flight of the aircraft while the aircraft is operating in a first condition, apply first control laws to automatically control the flight of the aircraft. The one or more processors are further configured to, in response to selection of the autopilot activation button while the aircraft is operating in a second condition, apply second control laws to automatically control the flight of the aircraft, where the second control laws are different from the first control laws.

A vehicle control method and a vehicle control device are configured to control the movement of a vehicle based on operation of a terminal device located outside the vehicle. The vehicle receives from the terminal device a first signal indicating that a first button of the terminal device has been pressed. The vehicle doors are unlocked based on the reception of the first signal, and the vehicle is placed in a state in which movement control is permitted.

An autonomous vehicle which includes multiple independent control systems that provide redundancy as to specific and critical safety situations which may be encountered when the autonomous vehicle is in operation.

A method is provided for adjusting a flight plan rejoining trajectory of an aircraft, the method being implemented in a flight management system of the aircraft. In a first step, the rejoining trajectory comprises a guidance setpoint holding point to be reached situated in the extension of a guidance setpoint, and set manually or automatically, the guidance setpoint no longer being necessarily maintained when this setpoint holding point is passed. This first step can be preceded by a step of rejoining a guidance setpoint or a step of searching for the intersection of the current guidance setpoint trajectory with a segment of the flight plan.

A method of operating an autonomous vehicle in a supervised autonomous mode is disclosed. A supervised autonomous mode can include the steps of receiving a vehicle data from a vehicle, presenting vehicle data at a remote station, receiving a supervisor input from a supervisor input device at the remote station, converting the supervisor input into a nudge for the motion planner of the vehicle associated with the received first set of vehicle data, wherein the nudge at least includes information on how to modify one or more elements of the cost function of the motion planner and transmitting the nudge from the remote station to the motion planner such that the nudge at least temporarily updates a cost function based model of the motion planner based on the nudge.

A method of operating an autonomous vehicle in a supervised autonomous mode is disclosed. A supervised autonomous mode can include the steps of receiving a vehicle data from a vehicle, presenting vehicle data at a remote station, receiving a supervisor input from a supervisor input device at the remote station, converting the supervisor input into a nudge for the motion planner of the vehicle associated with the received first set of vehicle data, wherein the nudge at least includes information on how to modify one or more elements of the cost function of the motion planner and transmitting the nudge from the remote station to the motion planner such that the nudge at least temporarily updates a cost function based model of the motion planner based on the nudge.

A flight management system for an aircraft, includes a critical first avionics module for trajectory calculation, i.e. a module the integrity level and availability level of which are specified by regulatory standards in force, delivering as output a safe trajectory, based on a flight plan; a second module for trajectory calculation that is less critical than the critical first module, i.e. a module the integrity level and availability level of which are lower than those of the first module, delivering as output an improved trajectory that is less safe than the trajectory delivered by the critical first avionics module, based on a flight plan; a critical avionics module for trajectory verification, configured to validate or invalidate the safety of the less safe improved trajectory; and a critical avionics module for decision-making configured to select a trajectory from the safe trajectory and the less safe trajectory.

According to one aspect, a method includes autonomously operating a vehicle along a first path, identifying a work zone, and determining whether the vehicle is able to continue operating along the first path after identifying the work zone. When it is determined that the vehicle is not able to continue operating along the first path, it is determined whether an autonomy system is able to identify a second path that routes around the work zone. When the autonomy system is able to identify the second path, the vehicle is autonomously operated along the second path. When the autonomy system is unable to identify the second path, the method includes requesting assistance from a teleoperations monitor arrangement. The vehicle is configured to obtain, from the teleoperations monitor arrangement, a waypoint or a first indication of a teleoperations operation arrangement assigned to remotely operate the vehicle around the work zone.

A path planning system for an agricultural machine performing self-driving includes a storage to store a map including fields and a road around the fields, and a processor to generate a path for the agricultural machine on the map. The processor is configured or programmed to generate a first path along which the agricultural machine is to travel while performing agricultural work in any of the fields, the first path being generated on the corresponding field on the map, and generate a second path along which the agricultural machine is to travel toward the field, the second path being generated on the road on the map.

A vehicular system includes a measuring unit attached to a vehicle to detect a magnetic marker laid along a traveling road, a database storing position information of the magnetic marker, and a control unit that acquires the position information of the magnetic marker by referring to a storage area of the database. The database has stored therein position information of each magnetic marker to which a distance from a reference point on the traveling road as a starting point to each magnetic marker is linked. By referring to the database by using a distance traveled until the magnetic marker is detected after the vehicle passes over the reference point, position information of newly detected magnetic marker is acquired.