An automatic driving assistance apparatus includes a driving state acquirer, an own vehicle location acquirer, a traveling environment information acquirer, a branch lane determining unit, a lane change calculator, and a traveling state controller. The driving state acquirer acquires a driving state of an own vehicle. The own vehicle location acquirer acquires a location of the own vehicle. The traveling environment acquirer acquires a traveling environment in which the own vehicle is traveling. The branch lane determining unit examines whether a target travel path toward which the own vehicle travels is set to a branch lane direction. The lane change calculator obtains a deceleration start position and a lane change start position of the own vehicle. The traveling state controller controls a traveling state of the own vehicle based on the deceleration start position and the lane change start position.

Systems and methods are provided for autonomous vehicle navigation. The systems and methods may map a lane mark, may map a directional arrow, selectively harvest road information based on data quality, map road segment free spaces, map traffic lights and determine traffic light relevancy, and map traffic lights and associated traffic light cycle times.

Provided is a steering assist apparatus configured to perform a steering assist control for changing a steering angle of a vehicle in such a manner that the vehicle moves along a target path; determine whether a newly-detected object is a stationary object or a moving object; cancel the steering assist control and inform a driver that the steering assist control is cancelled when the newly-detected object is the stationary object and a cancel condition is satisfied; pause the steering assist control and inform the driver that the steering assist control is paused when the newly-detected object is the moving object and a pause condition is satisfied; and resume the steering assist control when a resume condition is satisfied.

A steer-by-wire system comprises a steering shaft connected to a steering wheel; and a mechanical stop defining end-to-end travel limits of the steering shaft, the end-to-end travel limits comprising a first travel limit end of a first direction and a second travel limit end of a second direction opposite to the first direction. A controller rotates, in response to a signal related to first preset condition(s), the steering shaft toward the first direction until the steering shaft reaches the first travel limit end. And, the controller rotates, in response to a signal related to second preset condition(s), the steering shaft toward the second direction until the steering shaft reaches the second travel limit end. The system can prevent the rotation of the steering wheel using end-to-end travel limits of a mechanical stop of the steering shaft without a locking mechanism when the driver enters or exits the vehicle.

Systems and methods are disclosed for determining that an adverse driving event is likely to occur and utilizing accident calculus algorithms to determine and cause vehicle driving actions necessary to mitigate consequences of the adverse driving event. After determining that an adverse driving event is likely to occur, a computing device my forecast consequences of the driving event. The computing device may determine potential evasive maneuvers that may be taken responsive to the adverse driving event. Additionally, the computing device may determine consequences associated with the potential evasive maneuvers and assign a weight relative to the consequence. The computing device may compare the potential driving maneuvers based on the weighted consequences to determine a driving maneuver to take.

A system for vehicle navigation is provided. The system includes at least one processing circuitry programmed to receive via a data interface one or more images captured by one or more cameras representative of an environment of a vehicle, identify, based on analysis of the one or more images, at least one direction of at least one directional arrow on a road surface in the one or more images, determine a direction of travel for the vehicle based on the at least one direction of the at least one directional arrow on the road surface, determine at least one navigational action for the vehicle based on the determined direction of travel for the vehicle, and cause one or more actuator systems of the vehicle to implement the determined at least one navigational action for the vehicle.

A detection ECU detects left and right lane lines that define a driving lane from an image captured by an in-vehicle camera, by detecting a roadside as a side of a road where the own vehicle travels, from information of reflected waves received from a radar device. The detection ECU determines whether an estimated width indicating the width of a detected roadside and a detected lane line on a roadside side is narrower than the predetermined width. When the detection ECU determines that the estimated width is narrower than the predetermined width, it sets the predetermined position to be a position distant from the lane line on a roadside side in the estimated driving lane, than when the estimated width is determined not to be narrower than the predetermined width.

Provided is a steering assist apparatus configured to perform a steering assist control for changing a steering angle of a vehicle in such a manner that the vehicle moves along a target path; determine whether a newly-detected object is a stationary object or a moving object; cancel the steering assist control and inform a driver that the steering assist control is cancelled when the newly-detected object is the stationary object and a cancel condition is satisfied; pause the steering assist control and inform the driver that the steering assist control is paused when the newly-detected object is the moving object and a pause condition is satisfied; and resume the steering assist control when a resume condition is satisfied.

In accordance with an example embodiment, a vehicle includes a moveable member, posture sensing system, bird's-eye camera system, display, and controller. The posture sensing system indicates the moveable member's posture. The bird's-eye camera system provides images of its field of view, including the ground adjacent to the vehicle. The controller receives a posture signal from the posture sensing system, receives images from the camera system, creates a rendered vehicle representation, creates a rendered path projection, and generates a dynamically augmented bird's-eye view then displays it on the display. The moveable member is positioned in the rendered vehicle representation using the posture signal. The rendered path projection includes an outer envelope line projecting the path of an outermost point of the vehicle, determined using the posture signal. The dynamically augmented bird's-eye view is generated using the images, rendered vehicle representation, and rendered path projection.

A motor-driven power steering apparatus includes an auxiliary output generation unit configured to generate an auxiliary output of a motor by using at least one of a vehicle speed, a steering angle and a column torque; a compensation gain generation unit configured to generate a compensation gain for compensating for a steering pull of a vehicle by a rapid acceleration during a turn, by using at least one of the vehicle speed, the steering angle and the column torque; and an auxiliary output compensation unit configured to compensate for an auxiliary output by applying the compensation gain outputted by the compensation gain generation unit to the auxiliary output.