A vehicle such as a motor car (V) equipped with a radio equipment (14) is provided with a rearview camera 5 (10). Video frames from the rearview camera (10) are received at the radio equipment (14) and transmitted to a mobile communication device (S) such as a smart phone equipped with a video screen (S1) so that video frames from the rearview camera (10) are displayed on the 10 video screen (S1) of the mobile communication device (S).

Systems and methods for a rear-viewing camera system for a vehicle. A first camera is mounted on the vehicle with a field of view that is at least partially obstructed by a tailgate of the vehicle and/or a load carried by the vehicle. A second camera is mounted on the vehicle with a field of view that includes an unobstructed view of an imaging area that is obstructed in the field of view of the first camera. A tailgate position sensor is configured to output a signal indicative of a current position of the tailgate of the vehicle. By determining a position of the tailgate, an electronic controller is configured to generate an output image in which the tailgate and/or the load appear at least partially transparent by replacing image data that is obstructed in the image captured by the first camera with image data captured by the second camera.

A vehicle includes a cabin and a vehicle body including a cargo area rearward of the cabin. A tailgate assembly is mounted to the vehicle body that closes the cargo area. The tailgate assembly includes a rear-mounted video camera. An electronic control unit receives image data from the rear-mounted video camera. A connector communicatively couples the electronic control unit and the rear-mounted video camera. The connector has a closed configuration with the tailgate assembly mounted to the vehicle body and an open configuration with the tailgate assembly removed from the vehicle body. The electronic control unit includes logic that, wherein executed by a processor, causes the electronic control unit to receive signals from an alarm circuit when the connector is in the closed configuration and detect when the signals from the alarm circuit have stopped when the connector is in the open configuration.

A vehicular trailer hitching assist system includes a rear backup camera disposed at a rear portion of a vehicle and a control disposed in the vehicle. A display device includes a video display screen operable to display video images for viewing by a driver of the vehicle. Responsive to the driver initiating a hitching maneuver event by engaging reverse gear of the vehicle, rear backup video images derived from image data captured by the rear backup camera are displayed at the video display screen. An overlay overlays the displayed rear backup video images and aids in guiding connection of a trailer hitch of the equipped vehicle to a trailer tongue of a trailer. Continued display of rear backup video images that are overlaid by the overlay is ceased upon elapse of a threshold period of time or upon exceeding a threshold speed or upon exceeding a threshold distance traveled.

A camera monitor system including a first mirror replacement assembly including a housing supporting a rear facing camera and a rear facing range sensor, a controller in communication with the mirror replacement assembly, the controller including a processor and a memory, the memory storing instructions for identifying at least one object in an image feed from the camera and determining an angular position of the object using image analysis, identifying a distance of the at least one object from the mirror replacement assembly using the range sensor; and fusing the distance and the angular position of the object into a single data set, and a display connected to the controller and configured to display a mirror replacement view including at least a portion of the image feed.

A light-diffusing optical element with efficient coupling to light sources with high numerical aperture. The light-diffusing optical element includes a higher index core surrounded by a lower index cladding. The cladding includes scattering centers that scatter evanescent light entering the cladding from the core. The scattered light exits the element to provide broad-area illumination along the element. Scattering centers include dopants, nanoparticles and/or internal voids. The core may also include scattering centers. The core is glass and the cladding may be glass or a polymer. The element features high numerical aperture and high scattering efficiency.

Methods, systems, and vehicles are provided that include information systems including a display disposed about the interior of a vehicle. The display is positioned within the vehicle to be viewable by an occupant of the vehicle who is not looking forward through the vehicle windshield and/or or towards displays, gauges or instrumentation primarily positioned for viewing by a forward-looking occupant. The information system may be coupled to receive data from one or more vehicle control systems or controllers, from cameras disposed within the interior or on the exterior of the vehicle, from one or more sensors and/or from a telematics system. The information system configures the data for display on the display.

A vision system for a vehicle includes a forward viewing camera disposed at a mirror head of an interior rearview mirror assembly of the vehicle and having a forward field of view through the windshield of the vehicle. A sensor is disposed at the mirror head and determines a change in position of the mirror head relative to a mirror mount of the mirror assembly when the vehicle driver adjusts the mirror head. A control includes a processor operable to process image data captured by the forward viewing camera. Responsive to determination by the sensor of a change of position of the forward viewing camera relative to the mirror mount, the control selects an active sub-array of photosensors to provide an effective field of view of the forward viewing camera. The processor processes image data captured by the active sub-array of photosensors for a driver assistance system of the vehicle.

A motor vehicle includes a left side view camera attached to the left lateral side of the body and having a field of view in a rearward direction. A right side view camera is attached to the right lateral side of the body and has a field of view in a rearward direction. There is a right back up camera and a left back up camera. An optics module receives resulting video signals and produces light fields such that the light fields are reflected off of windows of the motor vehicle and are then visible to a driver of the motor vehicle as virtual images.

The present invention relates to a vehicle display device comprising: a display unit comprising a transparent flexible display disposed in a state of being rolled around a certain axis; a driving unit for adjusting the length of a region, of the transparent flexible display, exposed inside the vehicle; and a processor for controlling the driving unit and controlling the display of a picture on the transparent flexible display.