An automatic panning system and method adapted for a vehicle with an attached trailer. The automatic panning system comprises an image capturing means adapted to capture image data with a view of the trailer and the automatic panning system is adapted to analyze the image data to identify at least one elongated element of the trailer, project a vector in the image data based on said elongated element, establish at least one reference vector, and identify an interception point of the reference vector and said projected vector.

Methods and systems for detecting a surrounding environment around a vehicle and a trailer coupled to the vehicle. The system includes a plurality of cameras attached to and configured to detect image data. The system also includes an electronic control unit (ECU) of the vehicle communicatively coupled to the plurality of cameras and configured to combine the image data from the plurality of cameras.

The exemplary embodiments relate to a parking assistance system for a vehicle, designed to present surroundings of the vehicle. The parking assistance system can include at least one camera designed to record at least one image. The parking assistance system may use a grid structure to present the surroundings of the vehicle for a user. Additionally, the parking assistance system may have an image evaluation unit designed to determine the relative position and the orientation of another vehicle depicted in the image. Additionally, the image evaluation unit may be designed to adapt a grid structure on the basis of the determined orientation of the other vehicle, with the image being projected onto the adapted grid structure.

A rotary imaging device for wheels and an automobile are disclosed. The rotary imaging device for wheels includes a housing matched with the wheels, and a processing component, a display component and a power supply that are installed in the housing, the processing component being electrically connected with the display component and the processing component and the display component being both electrically connected with the power supply. The processing component is configured to send received or read to-be-displayed content to the display component after preset processing, and the display component is configured to display the to-be-displayed content sent by the processing component. According to the rotary imaging device for wheels and the automobile, images or videos can be formed through rotation of the wheels.

A vehicle vision system including an isolation block configured to compress under pressure, a rigid block on an interface surface of the isolation block configured to distribute pressure across the interface surface of the isolation block, the rigid block including a first protrusion extending away from the interface surface and having a cavity, and a camera embedded within the cavity and configured to capture video images.

An interactive vehicle safety system having capabilities to improve peripheral vision, provide warning, and improve reaction time for operators of vehicles. For example, the interactive vehicle safety system may have capabilities for portraying objects, which are being blocked by any of the structural pillars and/or mirrors of a vehicle (such as a truck, van, train, etc.). The interactive vehicle safety system disclosed may comprise one or more image capturing devices (such as camera, sensor, laser), distance and object sensors (such as ultrasonic sensor, LIDAR radar sensor, photoelectric sensor, and infrared sensor), a real-time image processing of an object, and one or more display systems (such as LCD or LED displays). The interactive vehicle safety system may give a seamless 360-degree front panoramic view to a driver.

A rearward camera of a vehicle electronic mirror system images a rearward view of a vehicle, and a lateral rearward camera unit images each of right and left lateral rearward views of the vehicle. A control device compresses at least one of a rearward view picture after imaging by the rearward camera and right and left lateral rearward view pictures after imaging by the lateral rearward camera unit, at least in a vehicle-width direction, and performs display on an inner mirror display. The control device changes the compression ratio of the picture in the control device, depending on at least one of a state and peripheral situation of the vehicle. Accordingly, when a vehicle rearward side including lateral rearward sides contains a site requiring an easy distance-sense grasp, it is possible to easily grasp distance sense by decreasing the compression ratio of the picture corresponding to the site.

A vehicle periphery display device includes: an acquisition portion acquiring a captured image obtained by imaging a periphery of a vehicle with an imaging portion; and a display processing portion causing a display image that is a stereoscopic image of the vehicle and the periphery of the vehicle to be displayed on a display portion on the basis of the captured image. The display processing portion causes at least one of a contour guide line representing a contour of the vehicle, and a predicted course guide line that is a trajectory drawn by the contour guide line according to movement of the vehicle to be included in the display image, and changes a position of at least one of the contour guide and predicted course guide lines such that the contour guide and predicted course guide lines are present above a road surface when the vehicle is turned.

Embodiments of the disclosure provide a camera system and a sensing method using such a camera system. The camera system includes a plurality of distributed cameras, collectively keeping a predetermined image space relative to the camera system in focus. The plurality of cameras are configured to capture image data of at least one object located in the predetermined image space. The camera system further includes a controller configured to determine position information of the at least one object relative to the camera system based on the image data.

A vehicle display control device includes a first image acquisition unit that acquires a first image by a first camera unit, a second image acquisition unit that acquires a second image by a second camera unit, a bird's-eye view image generation unit that generates a bird's-eye view image where a virtual vehicle image is synthesized at a center thereof based on the second image, a detection unit that performs an object recognition processing on the first image to detect a warning object, a direction calculation unit that calculates a direction of the warning object from the virtual vehicle image on a position of the warning object, and a display controller that displays the first image on a first monitor, and the bird's-eye view image and the direction of the warning object therein on a second monitor based on a position of the first camera unit in the vehicle image.