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.

The present embodiment relates to image acquisition and, in particular, to an image acquisition apparatus for acquiring images by a camera installed in a vehicle, and a method therefor. The image acquisition apparatus according to the present embodiment comprises: a projector for illuminating a reference pattern to the ground; a first camera unit for capturing an image of the reference pattern illuminated by the projector; a second camera unit for capturing an image; and a control unit for analyzing a pattern captured by the first camera unit and processing the image captured by the second camera unit.

An image display apparatus has: a first imaging device (11B) for imaging an area on the rear of a vehicle (1); a second imaging device (11BL, 11BR) for imaging an area on the rear and side of the vehicle; a synthesizing device (12) for generating a synthesized image in which a first image captured by the first imaging device and a second image captured by the second imaging device are adjacent to each other and a vanishing point of the first image in the synthesized image is different from a vanishing point of the second image in the synthesized image; and a displaying device (13) for displaying the synthesized image.

The present disclosure relates to a vehicle imaging system (1). More particularly, the present disclosure relates to a video data transmitter (3) for use with a vehicle (V). The video data transmitter (3) comprises a camera (5) for generating video data (D.sub.V). An image processor (15) is configured to process the video data (D.sub.V) and a transmitter (14) is provided to transmit the processed video data (D.sub.VP) to a video data receiver (2). The image processor (15) is configured to process the video data (D.sub.V) in dependence on one or more operating parameter of the vehicle (V). The present disclosure also relates to a video data receiver (2); and to a method of controlling transmission of video data (D.sub.V).

A vehicle includes a camera for capturing a rear image and effectively outputs a rear image captured through a mobile device when the vehicle does not include a display. A method of providing the rear image of the vehicle includes: setting a data path with a smart device, acquiring a rear image from a rear camera of the vehicle, correcting the acquired rear image based on a vehicle speed and delay that occurs in the data path, and transmitting the corrected image to the smart device.

According to one embodiment, an image synthesis device for an electronic mirror includes a rear camera which obtains a first image from a first position, and a side camera which obtains a second image of the same direction with a view of the rear camera from a second position. The second image includes a view obstruction. When a part of the first image is connected as a complementary image to the view obstruction of the second image, an image processing device converts an image of the view obstruction into a translucent image, superimposes the complementary image on the translucent image, and obtains a third image which remains an outline of the complementary image.

In a periphery monitoring apparatus, a display processing unit displays, in a display apparatus that is provided in a vehicle, a plurality of captured images that are acquired by a plurality of cameras provided in a plurality of differing positions in the vehicle and have overlapping portions in which portions of imaging areas overlap each other, such that the overlapping portions remain. A determining unit determines whether a predetermined target object to be detected is present in each of the plurality of captured images. The display processing unit includes an enlargement processing unit that enlarges at least one captured image in which the target object is determined to be present, among the plurality of captured images, and displays the captured image in the display apparatus when the determining unit determines that the target object is present in at least one of the plurality of captured images.

A capturing device includes an image sensor that generates an image signal by performing photoelectric conversion for light from a subject, a control unit that generates a setting value for setting a range where an image resulting from the image signal is cut, based on a first instruction input from a user, a setting value storage unit that stores the setting value generated by the control unit, an image conversion unit that reads the setting value from the setting value storage unit, and cuts a specific region specified by the setting value from the image and enlarges the cut region, when there is a second instruction input from the user, and an output unit that converts a signal of the image cut and enlarged by the image conversion unit into an image signal of a predetermined format and outputs the converted image signal.

A user interface apparatus for a vehicle includes: an interface unit; a display unit configured to project an augmented reality (AR) graphic object onto a screen; at least one processor; and a computer-readable medium coupled to the at least one processor having stored thereon instructions which, when executed by the at least one processor, causes the at least one processor to perform operations including: acquiring, through the interface unit, front view image information and vehicle motion information; based on the front view image information, generating the AR graphic object; and based on the vehicle motion information, warping the AR graphic object.

Disclosed are systems, methods, and non-transitory computer-readable media for adjusting depth of AR content on HUD. A viewing device identifies, based on sensor data, a physical object visible through a transparent display of the vehicle. The sensor data indicates an initial distance of the physical object from the vehicle. The viewing device gathers virtual content corresponding to the physical object and generates an initial presentation of the virtual content based on the initial distance. The viewing device presents the initial presentation of the virtual content on the transparent display at a position on the transparent display corresponding to the physical object. The viewing device determines, based on updated sensor data, an updated distance of the physical object and generates an updated presentation of the virtual content based on the updated distance. The viewing device presents the updated presentation of the virtual content on the transparent display of the vehicle.