A vehicular control system includes a central control module vehicle, a plurality of image capture sensors, at least one radar sensor and at least one lidar sensor disposed at an equipped. The central control module receives vehicle data relating to operation of the vehicle. During a driving maneuver of the vehicle, and responsive at least in part to fusion at the central control module of (i) captured image data, (ii) captured radar data and (iii) captured lidar data, a pedestrian or other vehicle may be detected or the speed of the equipped vehicle may be controlled. Responsive to the central control module determining that the detected pedestrian constitutes a potentially hazardous driving condition for the equipped vehicle, the central control module may control at least one selected from the group consisting of (i) braking of the equipped vehicle and (ii) steering of the equipped vehicle.

A vehicle lighting apparatus includes a first housing, a second housing, two lamp bodies, and two external cameras. The first housing and the second housing are formed separately from each other, joined to be adjacent in the front-rear direction, and arranged to cover a portion of the upper portion of a vehicle interior. The first housing includes a box portion. The second housing includes a wall portion closing a second opening portion of the box portion. An upper first end portion and a lower second end portion at the peripheral edge of the second opening portion of the box portion are joined to an upper third end portion and a lower fourth end portion of the wall portion. The first end portion and the third end portion are arranged relatively closer to the first housing side than the second end portion and the fourth end portion in the front-rear direction.

A device for controlling emotional lighting of a vehicle allows a driver and a passenger of the vehicle to emotionally view an external landscape through a door glass. Such a device includes: a camera for recording a video of a surrounding region of the vehicle; an emotional lighting device for irradiating light toward the door glass of the vehicle; and a controller for controlling the emotional lighting device to detect a representative color within the video of the surrounding region and irradiate light of a color corresponding to the representative color.

An external rearview device for a motor vehicle includes a housing, and one or more of at least one light emitting or a receiving device, including one or more of at least one light producing device or at least one camera device arranged within the housing, and at least one at least partially transparent element closing an opening provided by the housing, the at least partially transparent element being provided in form of a first module attached to the housing, and the one or more of the light producing device or the camera device being provided in form of a second module attached to the first module, the first module and the second module being mechanically releaseably coupled.

A system for calibrating a backup assist system for a trailer attached to a vehicle is provided which includes a hitch sensor continuously measuring a hitch angle between the vehicle and the trailer. A controller is configured to determine an offset of the measured hitch angle. The controller is configured to calculate and store in memory a forward offset if no reverse offset is stored.

A vehicle control system for moving a vehicle to a target location is disclosed. According to examples of the disclosure, a camera captures one or more images of a known object corresponding to the target location. An on-board computer having stored thereon information about the known object can process the one or more images to determine vehicle location with respect to the known object. The system can use the vehicle's determined location and a feedback controller to move the vehicle to the target location.

A vehicle hatch clearance determining system includes a plurality of cameras disposed at the vehicle and a control having a processor for processing image data captured by the cameras to determine structure and objects present in the fields of view of the cameras while the vehicle is being driven during a parking event. The control, responsive to processing of captured image data, determines and stores information pertaining to structure and objects present in the fields of view of the cameras during the parking event. When the vehicle is parked, the control determines if stored information includes structure or an object at or near the parking location and in a region that may be swept by the vehicle hatch when it is opened or closed. Responsive to determination of a potential collision of the hatch with structure or an object, the clearance determining system controls the hatch and/or generates an alert.

The present disclosure provides a visual perception method, an apparatus, a device and a medium based on an autonomous vehicle, the method includes inputting an obtained first visual perception image collected by the autonomous vehicle into a first neural network model, recognizing multi-channel feature information of at least one target recognition object to be recognized, to eliminate redundant feature information in the first visual perception image; further, inputting the multi-channel feature information of the at least one target recognition object to be recognized into at least one sub-neural network model in a second neural network model respectively, to obtain at least one target recognition object; where there is a one to one correspondence between the target recognition object and the sub-neural network model. The present disclosure improves the speed of recognizing the target recognition object, thereby improving sensitivity of the autonomous vehicle and ensuring driving safety of the autonomous vehicle.

A method is provided for driver assistance in order to avoid a collision of a bodywork side on an inside of a curve, or of a rear wheel on the inside of the curve, with an obstacle in a turning direction of a motor vehicle. The method creates an environment model that specifies an immediate environment of the motor vehicle together with potential obstacles in the turning direction; measures a steering-angle of the motor vehicle; creates a prospective driving trajectory of the motor vehicle as a function of the measured steering-angle; and outputs a warning function when the prospective driving trajectory indicates a probable contact of the motor vehicle with at least one obstacle.

A display controller includes: an image data acquisition unit that acquires image data as a result of capturing an image with an image capturing unit which captures an image of a situation around a vehicle; and a display processing unit that displays a display screen which includes a first region displaying a surrounding image that is generated based on the image data and indicates the situation around the vehicle and a second region other than the first region on a display unit, and changes a display mode of at least a part of at least one of the first region and the second region on the display screen depending on whether or not proxy control is executed to perform at least a part of a driving operation of the vehicle by proxy for a driver.