An example method to control an autonomous vehicle includes receiving a first signal and receiving a second signal. The first signal includes a first set of parameters that define a planned trajectory for the autonomous vehicle. The second signal includes a second set of parameters that define a planned trajectory for the autonomous vehicle. The method also includes generating a third signal by modifying the first set of parameters of the first signal to include the second set of parameters of the second signal. The method also includes outputting the third signal.

This disclosure provides systems and methods for controlling a vehicle by teleoperation based on a speed limiter. The method may include: receiving, at the autonomous vehicle, a teleoperation input from a teleoperation system, wherein the teleoperation input comprises a throttle control input for remotely controlling a speed of the autonomous vehicle; determining the speed of the autonomous vehicle; determining if the speed of the autonomous vehicle has reached a threshold speed below a speed limit; and upon determining that the speed of the autonomous vehicle has reached the threshold speed, reducing effect of the throttle control input from the teleoperation system such that an acceleration rate of the speed of the autonomous vehicle is reduced.

Embodiments relate to an aircraft control and interface system configured to adaptively control an aircraft according to different flight states by modifying one or more processing control loops. The system receives sensor data from one or more sensors of the aircraft. The system determines, from the sensor data, a component of the aircraft is compromised. The system determines the aircraft is in a degraded flight state due to the compromised component. The system operates the aircraft according to the degraded flight state, wherein operating the aircraft according to the degraded flight state includes: (a) modifying one or more processing loops based on the degraded flight state and (b) generating an actuator command by applying the degraded flight state and a signal based on an input from a vehicle control interface to the modified one or more processing loops.

Systems and methods for hailing and using an autonomous storage vehicle. A user uses the storage vehicle to store goods purchased. The storage vehicle carries the goods and stays in a designated area nearby. The storage vehicle goes to the user only when the user calls it. The user meets with the storage vehicle in a meeting area of a parking lot to retrieve the goods.

A method of operating an electrically powered rotorcraft of the type having a fuselage and a set of N rotors driven by a set of electric motors and coupled to the fuselage, N?4, under a failure condition preventing ordinary operation of the rotorcraft. The method includes entering a failsafe mode of operation wherein autorotation of at least four of the rotors is enabled. The method also includes using electrical braking associated with a selected group of the rotors to control pitch, roll and yaw of the rotorcraft.

In a marker detection system for a vehicle including a magnetic sensor to detect a magnetic marker laid in a road surface, the magnetic sensor can measures, for each axis, magnitudes of magnetic components acting along an axis in a vertical direction and an axis in a forwarding direction, and a detection unit identifies a candidate zone to which a possibility that the magnetic marker belongs is high, based on a change in a forwarding direction of the vehicle of a magnetic measurement value along any of the axes and determines whether the magnetic marker has been detected in accordance with a degree of synchronization between a first signal indicating a change of a magnetic measurement value regarding one axis in the candidate zone and a second signal indicating a change of a magnetic measurement value regarding the other axis in the candidate zone.

Solar power generation panels added on a transportation vehicle have a layout wherein power output of the panels varies according to an azimuth orientation of the vehicle. A controller includes a database of calibration curves relating an expected power output to a respective range of the azimuth orientation according to different solar altitude angles. A self-learning sequence is performed which (a) collects a magnitude of power output while the vehicle traverses the respective range of the azimuth orientation, (b) identifies a current solar altitude angle, and (c) stores a resulting calibration curve. A parking sequence comprises (a) selecting a calibration curve according to solar altitude angle, (b) determining a target vehicle azimuth angle which optimizes a cumulative power output based on the calibration curve and solar azimuth, and (d) initiating a movement of the vehicle to orient it at the target vehicle azimuth angle.

Systems and methods to increase environment awareness in remote driving applications may include a vehicle having an imaging device and a teleoperator station in communication with each other via a network. For example, audio data may be received from the vehicle and processed to identify known sounds associated with unseen objects in the environment. In addition, imaging data may be received from the vehicle and processed to identify known but unheard objects in the environment. Based on the identified sounds and/or objects, visualizations of the objects may be generated and presented to a teleoperator, and sounds associated with the objects may be amplified, synthesized, and/or emitted to the teleoperator to increase environment awareness.

A trailering support device able to facilitate loading of a hull onto a trailer includes one or more controllers configured or programmed to perform an automatic vessel steering control to move the hull toward the trailer; estimate, based on a content of the automatic vessel steering control, a position and an azimuth of the hull at a predetermined time after a start of the automatic vessel steering control; detect the position, a steering angle, and the azimuth of the hull; compare the estimated position and azimuth, respectively, with the position and the azimuth detected at the predetermined time; and determine, based on a comparison result, whether the loading of the hull onto the trailer able to be performed; and in a case where it is determined that the loading of the hull onto the trailer is not able to be performed, provide notification of the determination that the loading of the trailer is not able to be performed.

The present invention acquires surrounding information of surrounding environment of a vehicle; sets a virtual viewpoint position ahead of the vehicle in a traveling direction; uses the acquired surrounding information and generates virtual surrounding information indicating the surrounding environment at the set virtual viewpoint position; transmits a first control signal for controlling an external device located at a location away from the vehicle to display the generated virtual surrounding information; receives driving operation information on a driving operation of the vehicle output from the external device; generates driving assistance information for assisting driving of the vehicle based on the received driving operation information; and generates a second control signal for controlling an output device installed in the vehicle to output the driving assistance information.