A method of determining a trajectory of motion of a vehicle in a predetermined region, wherein the predetermined region includes a plurality of sub-regions, the method being executed by one or more processors, the method including determining an occupancy hypothesis of the predetermined region, wherein the occupancy hypothesis indicates occupied sub-regions of the plurality of sub-regions and non-occupied sub-regions of the plurality of sub-regions; determining a utility value for each sub-region of the predetermined region; determining the trajectory of motion which crosses at least one sub-region of the non-occupied sub-regions, based on a function of the utility values of the least one sub-region of the non-occupied sub-regions crossed by the trajectory of motion and by maximizing a utility of motion of the vehicle, wherein the utility of motion of the vehicle is indicated by a function of the utility values of the sub-regions crossed by the trajectory of motion.

A control unit for a vehicle having an active steering system capable of changing a steering gear ratio between a steering angle of a steering wheel and a tire steering angle includes a steering turning assist controller and a left-right driving force controller. The steering turning assist controller controls the steering gear ratio so that a yaw rate generated by the vehicle becomes a target yaw rate to assist a turning of the vehicle. The left-right driving force controller controls, in the left and right electric drive wheels which each add a yaw moment to a vehicle body independently of a steering system and are able to be independently driven, driving forces of the electric drive wheels so that the yaw rate generated by the vehicle becomes the target yaw rate based on a roll of the vehicle.

A sensor system for a vehicle including a first camera sensor and a second camera sensor configured to be mounted spaced apart from one another on a vehicle. A sensor module of the sensor system is configured to generate a three-dimensional image of an environment about the vehicle based on data collected by the first camera sensor and the second camera sensor.

A method and a device for transitioning a vehicle traveling with transverse guidance assistance into a driving state with a reduced collision risk in the event of a driver emergency, wherein the speed of the vehicle is greater than a predetermined threshold speed. The method includes detecting a hands-off situation of the driver in a hands-off phase, outputting a hands-off warning, performing a warning escalation in an escalation phase if there is no response to the hands-off warning, and reducing the vehicle speed in an intervention phase to a speed which is less than or equal to a threshold speed, the vehicle being kept in the current travel lane if there is no response to the warning escalation.

A vehicle collision avoidance assist system, including: a forward obstacle detecting device; and a controller including an automatic braking control executing portion to execute an automatic braking control for permitting a brake apparatus to automatically operate and an avoidance control executing portion to execute, in addition to the automatic braking control, an avoidance control for pen fitting a steering apparatus to automatically operate, wherein the avoidance control executing portion is configured such that, when the forward obstacle detecting device detects, as a forward obstacle, a continuous obstacle that continuously extends diagonally forward so as to be inclined with respect to a forwardly extending centerline that forwardly extends from a center of the own vehicle, the avoidance control executing portion executes the avoidance control to enable the own vehicle to avoid the continuous obstacle such that the own vehicle travels along the continuous obstacle.

Methods, apparatus, and articles of manufacture are disclosed for limiting a load applied to a rotatable shaft joint. An example apparatus comprises a comparator to, based on at least one of an angle of a rotatable shaft joint or a torque applied to the joint, determine whether at least one of the torque or the angle exceeds a threshold, and a limiter to limit at least one of the angle or the torque when at least one of the torque or the angle exceeds the threshold.

A method and a control unit for monitoring the lane of a vehicle, including the steps of ascertaining at least one lane characteristic, ascertaining at least one driving situation variable representing the instantaneous driving situation of the vehicle in an instantaneous position, as well as ascertaining at least one approach variable in a subsequent position of the vehicle. The approach variable is ascertained from the at least one lane characteristic, as well as from the at least one driving situation variable.

A method for controlling a manual driving mode includes manual mode detecting step detecting whether a vehicle switched from autonomous to manual mode; first step controlling angle of tire and steering angle of a steering wheel using travel route information when switching to manual mode is detected; delay time determination step determining a delay time of change of the angle of the tire with change of the steering angle of the steering wheel by the change in the angle of the tire with the change in the steering angle of the steering wheel for predetermined time; delay time comparison step comparing the determined delay time with predetermined time period; second step controlling only the steering angle of the steering wheel using travel route information when delay time is within the predetermined time period; and third step controlling angle of the tire by steering angle of the steering wheel.

Provided are a vehicle lane-changing control method and a vehicle lane-changing control device. The method includes controlling a host vehicle to travel into a neighboring to-be-turned-into lane with a first control rule, acquiring a location relation between the host vehicle and a referential lane line in a real time manner. The referential lane line is located between the host vehicle and the to-be-turned-into lane. The method further includes determining whether the location relation meets a preset changing rule, and controlling an action of the host vehicle with a second control rule corresponding to the preset changing rule in a case that the location relation meets the preset changing rule.

A parking assistance device according to an embodiment includes a determination unit that determines, when the parallel parking of a vehicle in a parking area is assisted, whether the parking space length of a frontage that the vehicle enters in the parking area is the sum of the full length of the vehicle and a certain length or more and a control unit that performs parking assistance for the vehicle along a route in which stationary steering control is not performed at a turning position of the vehicle when the parking space length is the sum of the full length of the vehicle and the certain length or more.