Abstract: A trajectory generation apparatus according to an embodiment includes an arithmetic unit capable of generating a positional trajectory of a movable part of a robot, in which: the arithmetic unit is further capable of generating a velocity trajectory of the movable part; and a predetermined time before switching a trajectory along which the movable part is moved from the velocity trajectory to the positional trajectory, the arithmetic unit predicts a position of the movable part at the time of the switching and generates the positional trajectory that starts from the predicted position.

Abstract: An information processing system includes a vehicle and an information processing device configured to transmit and receive information to and from the vehicle. The vehicle is configured to acquire information on an occupant in a cabin of the vehicle, and operate to affect a perception of the occupant. The information processing device is configured to store a cause of an accident caused by a passenger of the vehicle and control information for operating the operating unit to eliminate the cause of the accident, and transmit the control information to the operating unit of the vehicle when determination is made that the cause of the accident occurs based on the information on the occupant. The vehicle is configured to operate to eliminate the cause of the accident when the control information is received.

Abstract: A vehicle control method is disclosed. The vehicle control method includes: while controlling the driving of a vehicle taking control of itself, determining if there is a need to hand over the control of driving to a passenger in the vehicle; if it is determined that there is a need to hand over the control of driving to a passenger in the vehicle, selecting at least one of passengers to whom the control of driving may be handed over; determining an order of priority in handing over the control of driving by taking into consideration the at least one selected passenger's occupancy state information; handing over the control of driving to a top priority passenger according to the order of priority; and controlling the driving environment by taking into consideration the top priority passenger's occupancy state information.

Abstract: Systems, methods, and related technologies are disclosed for multi-device robot control. In one implementation, input(s) are received and provided to a personal assistant or another application or service. In response, command(s) directed to an external device are received, e.g., from the personal assistant. Based on the command(s), a robot is maneuvered in relation to a location associated with the external device. Transmission of instruction(s) from the robot to the external device is initiated.

Abstract: A method of adapting tuning parameter settings of a system (2) functionality (3) for road vehicle (1) speed adjustment control starting from initially selected settings and applying a training set of speed adjustment profiles obtained from manually negotiated road segments and road segment data for these. For each of these road segments: —a simulated speed adjustment profile is calculated using the selected settings and the road segment data; —the manual and the simulated speed adjustment profiles are compared to obtain a residual; —a norm of the residual is calculated. For all of the road segments of the training set: —a norm of the norms of the residuals is calculated; —at least one of optimization, regression analysis or machine-learning is performed to minimize the norm of the norms of the residuals by selecting different settings and iterating the above steps. Settings rendering a minimal training set norm are selected.

Abstract: A driving system for a motor vehicle includes a first driving function for automated driving with automated longitudinal and transverse guidance and a second driving function for automated driving with at least automated longitudinal guidance, or with at least automated transverse guidance. The second driving function has a lower degree of automation than the first driving function. The first driving function is available in a tolerance range. Starting from a driving state with an active second driving function and a value of the driving parameter outside the tolerance range, the driving system changes, when the second driving function is active, the value of the driving parameter in the direction of the tolerance range via automated longitudinal guidance or automated transverse guidance. The driving system then determines that the driving parameter satisfies a criterion with respect to the tolerance range.

Abstract: An apparatus for controlling remote parking in a vehicle is provided. The apparatus includes an ultrasonic sensor that measures a distance from the vehicle to an obstruction and a receiver that receives a surround view monitoring (SVM) image. A controller executes remote parking of the vehicle by selectively using the distance from the obstruction, the distance being measured by the ultrasonic sensor, and the SVM image received by the receiver.

Abstract: A method performs an at least partially automated maneuver. When an increased probability of collision of the vehicle with a vehicle in front is recognized, at least the decision to divert and/or the decision to return, i.e. the decision to return to the lane in which the vehicle was travelling before the diversion, is controlled as a function of a parameter of the traffic situation in front of the vehicle in front.

Abstract: A driving assist apparatus executes an autonomous braking control to autonomously stop a vehicle when a level of potential that the vehicle collides with an obstacle is larger than a predetermined level. The driving assist apparatus executes a stopped state keeping control to keep the vehicle stopped to prevent moving of the vehicle after the vehicle is stopped by the autonomous braking control. The driving assist apparatus performs a warning to warn a driver of the vehicle when the driver performs a mistaken pressing operation of mistakenly pressing an acceleration pedal with an intention to press a brake pedal. The driving assist apparatus changes a manner of performing the warning from a first manner to a second manner when the driving assist apparatus stops the vehicle by the autonomous braking control while the driving assist apparatus is performing the warning.

Abstract: Vehicle driving control apparatus having function for performing automated in-lane driving by maintaining a vehicle speed when no preceding vehicle is in driving lane, and maintaining an inter-vehicle distance when a preceding other vehicle exists, function for performing automated lane change when there is no other vehicle in a predetermined area of neighboring lane, a function for notifying a driver of stopping the functions and an operation takeover request when a system failure occurs, function for evacuating vehicle to road shoulder when driver cannot resume operation, wherein, when vehicle is not in first lane neighboring road shoulder at operation of evacuating function, lane change from in-lane driving maintaining set inter-vehicle distance or set vehicle speed to first lane is performed, and prior thereto, a predetermined area serving as criterion of lane change to first lane is changed to a second area smaller than area of automated lane change.

Abstract: A drive assistance system includes a primary target setter to designate an object determined based on a current movement locus of the own vehicle to be a primary target probably interfering with the own vehicle; a prediction locus estimation unit to estimate a prediction locus along which the own vehicle moves when primary avoidance control is executed in the own vehicle to avoid the interference with the primary target; and a secondary target setter to designate another object determined based on the prediction locus as a secondary target probably interfering with the own vehicle. The drive assistance system also includes a drive assistance controller to execute drive assistance control in the own vehicle based on a determination of whether the interference by the secondary target can be avoided by executing a secondary avoidance control in the own vehicle to avoid the interference by the secondary target.

Abstract: A computer includes a processor and a memory, the memory storing instructions executable by the processor to determine at least one of: a brake threat number of a host vehicle, a brake threat number of a target vehicle, a steering threat number, or an acceleration threat number and to actuate the host vehicle to change at least one of direction or speed based on at least one of the threat numbers. The brake threat number of the host vehicle is based on a predicted lateral distance between the host vehicle and the target vehicle. The brake threat number of the target vehicle is based on a velocity of the target vehicle adjusted by an acceleration of the target vehicle and an actuation time of a brake. The steering threat number is a lateral acceleration being a predicted lateral distance adjusted by an actuation time of a steering component. The acceleration threat number is based on a predicted lateral offset adjusted by a predicted heading angle of the host vehicle.

Abstract: An autonomous vehicle is operated using a main autonomy system that analyzes data collected by a sensor system of the autonomous vehicle to determine a trajectory of travel of the autonomous vehicle, and wherein the main autonomy system provides instructions to a propulsion system of the autonomous vehicle to cause the propulsion system to navigate the autonomous vehicle according to the trajectory. In response to determining that navigating the autonomous vehicle according to the trajectory is likely to result in collision, instructions are provided from a parallel autonomy system to the propulsion system to cause the autonomous vehicle to avoid collision. In response to detecting a fault in the main autonomy system, control of the propulsion system is provided from the main autonomy system to a failover autonomy system, wherein the failover autonomy system is configured to override the propulsion system.

Abstract: The present invention provides a control system and a control method capable of appropriately supporting driving of a motorcycle by a rider. The control system includes a control amount setting unit that sets a control amount in auto cruise operation, an execution unit that causes the motorcycle to execute the auto cruise operation, and further including a lane position information acquiring unit that acquires relative position information of a lane boundary with respect to the motorcycle during traveling, and a limitation determining unit that determines to provide a limitation on the auto cruise operation in a case where a determination reference is satisfied, in which the determination reference includes a condition that the lane position information acquired by the lane position information acquiring unit satisfies a prescribed condition.

Abstract: Embodiments of the present disclosure are directed towards a robotic system. The system may include a robot configured to receive an initial constrained approach for performing a robot task. The system may further include a graphical user interface in communication with the robot. The graphical user interface may be configured to allow a user to interact with the robot to determine an allowable range of robot poses associated with the robot task. The allowable range of robot poses may include fewer constraints than the initial constrained approach. The allowable range of poses may be based upon, at least in part, one or more degrees of symmetry associated with a workpiece associated with the robot task or an end effector associated with the robot. The system may also include a processor configured to communicate the allowable range of robot poses to the robot.

Abstract: A turning control device includes: a target steering angle calculation unit configured to calculate a target steering angle of a turning mechanism, based on a second steering angle of a steering mechanism; a steering angular displacement calculation unit configured to, when a third steering angle, the third steering angle being either a first steering angle of the turning mechanism or the second steering angle, is in a range from a maximum steering angle that the third steering angle can take to a first threshold steering angle, calculate a steering angular displacement of the third steering angle with the first threshold steering angle used as a reference; a steering angle correction value calculation unit configured to calculate a steering angle correction value according to at least the steering angular displacement; and a corrected target steering angle calculation unit configured to correct the target steering angle with the steering angle correction value.

Abstract: A vehicle driving controller, a system including the same, and a method thereof are provided. The vehicle driving controller includes a processor configured to apply a different warning level depending on at least one of a driving situation or a user state during autonomous driving and to provide a notification of a control authority transition demand to a user and a storage configured to store information associated with the driving situation and the user state and information associated with the different warning level.

Abstract: A vehicle steering control method, device and system, and a vehicle are provided. The vehicle steering control method includes: in a case where a current vehicle speed is less than a turning vehicle speed threshold, steering of a vehicle is controlled by an Electric Power Steering (EPS) to implement cornering of the vehicle; in a case where a cornering condition of the vehicle is not reached during the cornering of the vehicle, the vehicle is controlled by an Electrical Park Brake (EPB) to perform single-side parking to assist in the cornering of the vehicle; and after the single-side parking of the vehicle is implemented, closed-loop control is performed on an electric control booster, the EPB and the EPS, and the vehicle is controlled to turn under the cornering condition.

Abstract: A trusted accident avoidance control system supported on a vehicle operable to travel a path, and comprising at least first and second location determination components operable to estimate a current position of the vehicle. An error correction component can receive the estimated current position information from the first and second location determination components and determine an updated estimated current position of the vehicle based on these, wherein the error correction component can be operable with a path database to identify a predetermined threshold velocity for the updated estimated current position of the vehicle. A velocity management component can determine, based on the updated estimated current position, whether a current velocity of the vehicle exceeds the predetermined threshold velocity, and if so, initiate an accident avoidance measure.

Abstract: The solar energy and solar farms are used to generate energy and reduce dependence on oil (or for environmental purposes). The maintenance, operation, optimization, and repairs in big farms become very difficult, expensive, and inefficient, using human technicians. Thus, here, we teach using the robots with various functions and components, in various settings, for various purposes, to improve operations in big (or hard-to-access) farms, to automate, save money, reduce human mistakes, increase efficiency, or scale the solutions to very large scales or areas, e.g., for repair, operation, calibration, testing, maintenance, adjustment, cleaning, improving the efficiency, and tracking the Sun.