A parking assist system comprises a route generating unit for generating a generating position for generating a parking route for parking a vehicle in a determined parking space and for generating a travel route for the vehicle to travel to the generating position; and a control information generating unit for generating control information for the vehicle to travel along the travel route by controlling a driving system 80 for causing the vehicle to travel, and for outputting the generated control information to a vehicle controlling unit for controlling the driving system, wherein: the route generating unit determines a generating position such that at least a portion of the back end of the vehicle will be positioned within a parking space, and, after the vehicle has arrived at the generating position, generates, at the generating position, a parking route for the vehicle to park in the parking space.

The assembly mounted on a moving device includes an element, an optical system configured to form a high resolution image near an optical axis in a first region of a light receiving surface of the element and form a low resolution image of a peripheral portion separated from the optical axis in a second region wider than the first region of the light receiving surface of the element, a generation unit configured to generate a first captured image from pixel data in the first region and generate a second captured image from pixel data in the second region, and a control unit configured to selectively display the first captured image or the second captured image on a display unit in accordance with a moving direction of the moving device.

An apparatus for controlling a hybrid vehicle and a method thereof are provided. The apparatus includes a hybrid starter & generator (HSG) controller that determines whether an HSG has failed, and a hybrid vehicle controller that controls reverse drive by controlling locking up an engine clutch and maintaining a main relay of a battery to be continuously turned on, based on whether a request for the reverse drive is input from a user. The hybrid vehicle controller changes and applies a vehicle torque control calculation method based on a state of charge (SoC) of the battery, when the HSG has failed.

An automotive electronic dynamics control system for an automated motor-vehicle. The electronic dynamics control system is designed to implement two distinct Model Predictive Control (MPC)-based Trajectory Planners comprising a Longitudinal Trajectory Planner designed to compute a planned longitudinal trajectory for the automated motor-vehicle; and a Lateral Trajectory Planner designed to compute a planned lateral trajectory for the automated motor-vehicle. The electronic dynamics control system is further designed to cause the planned longitudinal trajectory to be computed before the planned lateral trajectory.

A monitoring area setting apparatus is mountable to an own vehicle and sets a monitoring area that indicates an area for monitoring objects in a vicinity of the own vehicle. The monitoring area setting apparatus acquires (i) at least either of a vehicle-width movement amount that indicates an amount of movement in a vehicle-width direction of the own vehicle and an inclination amount that indicates a degree of inclination of the own vehicle relative to an extending direction of a road on which the own vehicle is traveling, and (ii) information that the own vehicle has changed traffic lanes. The monitoring area setting apparatus sets the monitoring area taking into consideration at least either of the vehicle-width movement amount and the inclination amount in response to the own vehicle changing traffic lanes.

A method for automated lane keeping includes automatically positioning a vehicle at a normal position in a lane of a roadway with a lane-keeping system of the vehicle, and storing lane-offset data for a predetermined portion of the roadway. The lane-offset data correspond to an offset position of the vehicle in the lane of the roadway that is different from the normal position. The method further includes detecting that the vehicle is operating on the predetermined portion of the roadway, and automatically positioning the vehicle at the offset position with the lane-keeping system when the vehicle is operated on the predetermined portion of the roadway.

An on-board unit as a direction change detection device is configured to acquire a steered angle and a mileage of a vehicle at a time point at which a right turn event related to a right turn of the vehicle occurs when the right turn event occurs, and detect the right turn on condition that a maximum value of the steered angle is equal to or less than a first threshold value, and the mileage is equal to or greater than a second threshold value.

In response to a request for a three-point turn, a forward turning path from a current location and heading direction of the ADV is generated. In generating the forward turning path, a forward curvature is determined based on the maximum forward turning angle of the ADV by applying a full steering command. The forward turning path is determined based on the forward curvature from the current location of the ADV. A forward speed profile is calculated for the forward turning path based on perception information that perceives a driving environment surrounding the vehicle at the point in time. In addition, a backward turning path is generated from an end point of the forward turning path based on a maximum backward turning angle associated with the ADV. The three-point turn path is then generated based on the forward turning path and the backward turning path to drive the vehicle to make the three-point turn.

A vehicle slip control apparatus to be installed in a vehicle including a drive source configured to output power to a driving wheel of the vehicle and a gear pair interposed between an output shaft of the drive source and the driving wheel includes a rotating speed detector, a slip determination unit, and a slip determination prohibition unit. The rotating speed detector is configured to detect a rotating speed of the output shaft. The slip determination unit is configured to determine, when an absolute value of an angular acceleration of the rotating speed detected by the rotating speed detector exceeds a set threshold, that the driving wheel is in a slip state. The slip determination prohibition unit is configured to prohibit the determination by the slip determination unit until a predetermined time elapses after a direction of torque outputted from the drive source is inverted.

A method controls a first vehicle in respect of an oncoming second vehicle. The method determines a turning situation of the first vehicle, in which an expected first trajectory of the first vehicle crosses an expected second trajectory of the second vehicle, and controls the first vehicle in such a way that, during the turning situation, a predetermined distance between the vehicles is maintained. The control includes an influencing of the direction of travel of the first vehicle.