A system for assisting in aligning a vehicle for hitching with a trailer includes an imager outputting image data of a field of view to the rear of the vehicle and a controller identifying at least one of a trailer or a coupler of the trailer within the image data. The controller further determines that the at least one of the trailer or the coupler is outside of a specified area relative to the vehicle and outputs an instruction for movement of the vehicle determined to position the one of the trailer or the coupler within the specified area. Upon determining that the at least one of the coupler and the trailer is within the specified area, the coupler outputs a steering signal to the vehicle to cause the vehicle to steer to align a hitch ball of the vehicle with the coupler.

A vehicle hitching assistance system includes a controller acquiring image data from the vehicle and identifying a plurality of trailers within in a specified area of the image data. The specified area is less than a total field of the image data and corresponds at least with left and right steering angle limits of the vehicle. The controller further receives a selection of a subject trailer of the plurality of trailers identified within the specified area, identifies a coupler of the subject trailer, and outputs a steering signal to the vehicle to cause the vehicle to steer to align a hitch ball of the vehicle with the coupler of the subject trailer.

A vehicle hitching assistance system includes a controller executing an initial alignment process including searching for a trailer within a specified area of image data that is less than a total field of the image data in directions corresponding with both a longitudinal distance between the vehicle and the trailer and a lateral direction perpendicular to the longitudinal distance, presenting an indication to a driver of the vehicle to reposition the vehicle when the trailer is not identified within the specified area, and removing the indication when the trailer is identified within the specified area. The controller further executes an automated backing process upon identifying the trailer within the specified area, including identifying a coupler of the trailer and outputting a steering signal to the vehicle to cause the vehicle to steer to align a hitch ball of the vehicle with the coupler of the trailer during reversing.

A display image is obtained by superimposing an image showing a vehicle on a captured image obtained by capturing an image on a rear side from the vehicle. For example, the image showing the vehicle is a computer graphics image. For example, a change is made in a superimposed positional relationship between the captured image and the image showing the vehicle in accordance with motion of a viewpoint of a driver. Since the display image is not only made from the captured image obtained by capturing an image on a rear side from the vehicle, but the display image is obtained by superimposing the image showing the vehicle on the captured image, it is possible to easily provide a sense of distance by motion parallax.

Provided is an information processing device that includes an acquisition unit that acquires an image captured by an imaging unit, a recognition unit that recognizes attributes of an object shown in the image captured by the imaging unit, and a generation unit that generates a bird's-eye view map showing the attributes of the object on the basis of the image captured by the imaging unit and information on the attributes of the object recognized by the recognition unit.

The present invention relates to a computer-implemented method for generating a perspective-corrected overlay for an imaging system of a motor vehicle, to a method for generating a trimmed overlay for an imaging system of a motor vehicle, to devices for carrying out respective methods and to motor vehicles comprising an imaging system and such a device.

A digital imaging system and method of image data processing are provided. The system includes a main lens configured to focus light from a field of view for a plurality of depths of field and project a plurality of intermediary images representing the depths of field. An image sensor assembly is in a spaced relationship with the main lens and includes a light sensors grouped into sensor sub-arrays. An intermediate microlens array is disposed between the main lens and the image sensor assembly and includes intermediate micro lenses adjacent to and abutting one another to focus the intermediary images onto one of the sensor sub-arrays from a different perspective than another adjacent micro lens. A control unit captures and stores image data associated with the intermediary images and creates a three-dimensional depth map. The control unit also calculates distance information of objects to detect a gesture or obstacle.

A vehicle control device includes a display configured to display information, an inputter to which a user's operation is input, a driving controller configured to control at least one of a speed and steering of a vehicle, a determiner configured to determine a lane in which the vehicle is present when a first operation that allows a lane change by the vehicle is input to the inputter as a reference lane, and a display controller that is configured to cause the display to display a first image depicting a road on which the vehicle is present and a second image depicting the reference lane which are superimposed.

An in-car cloud VR device includes: a GIS information acquisition unit that detects a location of a vehicle through a GPS sensor installed in a traveling vehicle and acquires the GIS information near the vehicle; an thing information acquisition unit that collects videos around the vehicle through at least one camera sensor installed in the vehicle and acquires surrounding thing information around the vehicle; a movement information acquisition unit that acquires movement information of a user in the vehicle through at least one gyro sensor; and an FOV video determination unit that determines a first FOV video based on the GIS information, updates the first FOV video based on the surrounding thing information, and determines a second FOV video within the first FOV video based on the movement information of the user.

A vehicle control device includes a plurality of imaging units that images an outside world of a vehicle, a surrounding screen image composition unit that combines a plurality of captured images captured by the plurality of imaging units to generate a surrounding screen image, a collision determination unit that determines whether an obstacle is present on a traveling route of the vehicle, an alarm screen image generation unit that selects, from a plurality of captured images, a captured image in which the obstacle is imaged to generate an alarm screen image including the selected captured image, and a display screen image switching unit that performs a process of displaying the surrounding screen image when the collision determination unit determines that the obstacle is not present, and displaying the alarm screen image when the collision determination unit determines that the obstacle is present.