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 vehicular camera system includes an attaching structure configured to attach at an in-cabin side of a vehicle windshield. A camera module accommodates a circuit board having circuitry disposed at both sides of the circuit board. An imager is disposed at a first side of the circuit board. The camera module includes a lens accommodated in a lens barrel. With the attaching structure attached at the in-cabin side of the vehicle windshield, and with the camera module attached at the attaching structure, the lens barrel protrudes from the casing and a portion of the lens barrel is partially disposed in a pocket defined by the stray light shield and the vehicle windshield. A coaxial connector is electrically connected to circuitry disposed at the second side of the circuit board. Image data captured by the camera module is transferred to an electronic control unit of the vehicle via the coaxial connector.

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.

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.

A vehicle hitching assistance system includes a controller acquiring image data from the vehicle, identifying a plurality of trailers within the image data, receiving a selection of a subject trailer of the plurality of trailers, identifying a coupler of the subject 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 subject trailer.

A vehicle hitching assistance system includes a controller acquiring image data from the vehicle and identifying a trailer within a specified area of the image data and then identifying a coupler of the trailer. The specified area is less than a total field of the image data. The controller then 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 hitch assist system is provided herein. The hitch assist system includes an imager for capturing one or more images of a hitch assembly and a trailer coupler. The imager is operably coupled with a movable panel. The hitch assembly includes a ball mount and a hitch ball. A controller is configured to generate an image that includes the hitch assembly, identify the hitch assembly within the image, estimate a ball mount length based on a predefined reference length and/or estimate a hitch ball height.

A hitch assist system is provided herein that includes a sensing system configured to detect a trailer proximate a vehicle. The hitch assist system also includes a controller for detecting a coupler of the trailer; determining a trailer-heading direction-based on a coupler orientation; and determining a path for aligning a hitch assembly on the vehicle with a coupler on the trailer based on the trailer-heading direction.

A vehicle and a control method may determine a state of a vehicle or a slope of a road surface using an image acquired by the vehicle, and provide a top view image with less distortion by correcting the image based on the state of the vehicle and the slope of the road surface. The vehicle includes a display; an image acquiring unit to acquire an image around the vehicle; and a controller to change the image around the vehicle based on a difference between the image around the vehicle and a predetermined reference line and to output the changed image to the display.

A hitch assist system is provided herein that includes a sensing system configured to detect a trailer proximate a vehicle. The hitch assist system also includes a controller for detecting a coupler of the trailer; determining a trailer-heading direction-based on a coupler orientation; and determining a path for aligning a hitch assembly on the vehicle with a coupler on the trailer based on the trailer-heading direction.