A vehicle camera peripheral. It has a frame having a surface for supporting a license plate, at least one compartment for containing a battery and a circuit board having a wireless transmitter and video transmission circuitry, the compartment provided in the frame and positioned behind the license plate supporting surface, a camera mounted to the frame and connected to the circuit board, and a mounting for connecting the frame to existing license plate fastening devices of a vehicle.

An automotive audio visual system includes a display screen on the vehicle, such as the central display screen on the vehicle's dashboard, and one or more rear cameras facing a rear passenger seat of the vehicle. The image or video feed from one or more rear cameras is displayed on the display screen in the vehicle, so that the front passengers can view the rear passenger area on the vehicle's display screen.

A vehicle optical wireless data communication system includes a plurality of light sources disposed at a structure where vehicles travel. Each of the light sources emits visible light to illuminate the building or structure. Each of the light sources emits optical signals indicative of a location of the respective light source. A sensor is disposed at a vehicle and is operable to sense optical signals emitted by the light sources when the vehicle is in the vicinity of the light sources. Responsive to sensing by the sensor of optical signals emitted by at least one of the light sources, the sensor generates an output to a processor disposed at the vehicle. The processor processes the output of the sensor to determine a location of the vehicle relative to at least one of the light sources.

An inductively powered camera device including a housing including a base portion configured to be mounted to an exterior surface of a window of a vehicle, a camera supported by the housing and configured to collect image data, an inductive power pad supported by the housing, the inductive power pad in electrical communication with the camera and configured to provide power to the camera, and an inductive power puck configured to be mounted to an interior surface of the window, the inductive power puck configured to inductively provide power to the inductive power pad through the window of the vehicle.

A vehicle backing assistance system is described. The vehicle backing assistance system includes a first device and a second device. The first device includes a camera, a microphone, a light, an ultrasonic proximity sensor, a significantly waterproof body, and a battery. The first device can then be releasably connected to a rear end of a vehicle. Images, video, audio, and depth sensing are collected by the first device, which are then transmitted to the second device at a remote location. As a result, a user can monitor the images, video, audio, and depth sensing using software on the second device that are collected by the first device while located away from the second device. For instance, the user could monitor that rear end of a vehicle while being located at a front cab of the vehicle. This can be useful when the user is backing the vehicle.

The present disclosure relates to a display system (1) for generating a composite view of a region behind a vehicle (V) towing a trailer (T). A first camera (C1) is provided for outputting first image data corresponding to a first image (IMG1), the first camera (C1) being configured to be mounted in a rear-facing orientation to the vehicle (V). A second camera (C2) is provided for outputting second image data corresponding to a second image (IMG2), the second camera (C2) being configured to be mounted in a rear-facing orientation to the trailer (T). An image processor (5) receives the first image data and said second image data. The image processor (5) is configured to combine said first image data and said second image data to generate composite image data corresponding to a composite image (IMG3). The present disclosure also relates to a corresponding method of generating a composite image (IMG3), and to a rig made up of a vehicle (V) and a trailer (T).

A method for dynamically registering a graphic upon a cropped image obtained from a camera device includes capturing an original image obtained from the camera device. Intrinsic calibration information for the camera device, extrinsic information for the camera device and vehicle information are monitored. The cropped image is generated based on cropping parameters to exclude undesirable content from the original image. The intrinsic calibration information is adjusted based on a relationship to the cropping parameters. The graphic is dynamically registered upon the cropped image based on the adjusted intrinsic calibration information for the camera device, the monitored extrinsic information for the camera device and the monitored vehicle information.

A rear vision system and a corresponding method for use with a host vehicle towing a trailer or other object. The rear vision system may include a rear facing camera, a vehicle-to-vehicle (V2V) unit, vehicle dynamic sensors, a navigation unit, a control unit, and an electronic display mirror. When the towed trailer obstructs the rear facing camera, the system and method look for unseen vehicles behind the trailer and use the V2V unit to gather information from these vehicles. This information is then used to generate a rendering that graphically depicts or represents the unseen vehicle, and the rendering is superimposed on top of the video output from the rear facing camera in the form of enhanced video output, which is then displayed on the electronic display mirror. Thus, the driver is able to “see” behind the obstructing trailer without the use of additional cameras installed on the trailer.

A vision system for a vehicle towing a trailer includes a vehicle transceiver disposed at the vehicle and at least one trailer camera disposed at the trailer being towed by the vehicle and having a field of view exterior of the trailer. A trailer transceiver is disposed at a front exterior portion of the trailer and is operable to receive image data captured by the at least one trailer camera and to wirelessly transmit captured image data to the vehicle transceiver disposed at the vehicle when the vehicle is towing the trailer. A video display screen is disposed at the vehicle and viewable by a driver of the vehicle when the vehicle is towing the trailer. The video display screen is operable to display video images derived from captured image data received by the vehicle transceiver disposed at the vehicle.

The present disclosure provides a vehicle driving assistant apparatus, comprising: an infrared image acquiring module for acquiring information of an infrared image of an object ahead of a vehicle; a display module connected with the infrared image acquiring module, for displaying a corresponding image according to the information of the infrared image acquired by the infrared image acquiring module. The disclosure enables the driver to see the road conditions ahead by means of the vehicle driving assistant apparatus even when facing glaring light emitted from ahead when driving at night, thus reducing the occurrence of traffic accidents.