A rearview imaging system for a vehicle includes at least one video camera mounted at the rear of the vehicle for providing a wide angle horizontal field of view (FoV) rearwardly of the vehicle, and a display device in the vehicle at a position viewable by the driver. A video processor subdivides the camera FoV into three horizontally disposed sub-FOVs and displaying said sub-FoVs on visually separated side-by-side regions of the display device screen. The horizontal position and/or extent of at least one sub-FoV is variable as a function of the motion of the vehicle.

Displays for a vehicle can be used to display a composite feed from one or more cameras. In some examples, the vehicle display can be a rear-view mirror replacement display. In some examples, the vehicle can include feeds from a rear-view camera and two side-view cameras. The composite feed for the display can be adapted according to monitored conditions. For example, when a vehicle is detected in a blind spot, the composite feed can be adapted to add a feed from the corresponding side view camera. In some examples, when a vehicle is detected in the blind spot, the composite feed can be adapted to increase the proportion of the display area allocated to the side-view camera feed from the corresponding side-view camera. In some examples, when a vehicle is detected in the blind spot, the corresponding side-view camera view can be visually distinguished.

A side rear view camera is located at a driver or passenger side of the vehicle, captures video beside and behind the vehicle, and has a predetermined field of view (FOV). The predetermined FOV is defined by a first predetermined horizontal angle of view (AOV) and a first predetermined vertical AOV. A display is located and visible within a passenger cabin of the vehicle. A display module, on the display: displays a first portion of the video from within a first predetermined portion of the predetermined FOV, the first predetermined portion of the predetermined FOV being defined by a second predetermined horizontal AOV and a second predetermined vertical AOV; and selectively displays a second portion of the video from within a second predetermined portion of the predetermined FOV, the second predetermined portion of the predetermined FOV being defined by a third predetermined horizontal AOV and a third predetermined vertical AOV.

A vehicle display system includes a display unit, a camera controller, and a media controller. When the vehicle display system is in a normal mode, the display unit shows an output image of the camera controller if a transmission of a vehicle is in a reverse gear, and shows an output image of the media controller if the transmission of the vehicle is not in the reverse gear. When the vehicle display system is in a test mode, the display unit shows a test image selected by the media controller regardless of whether or not the transmission of the vehicle is in the reverse gear.

Disclosed is an apparatus for assisting a vehicle, including: a gear mounted in a vehicle and configured to switch an operation mode into any one of a travelling mode, a parking mode, a neutral mode, and a reverse mode of the vehicle; one or more lighting devices provided in the vehicle; a camera mounted in the vehicle, and configured to obtain an image around the vehicle; a processor configured to decrease a gain of a first color in an RGB image, which is received from the camera and includes light emitted from the taillight when the operation mode is switched into the reverse mode; and an output unit configured to output the image processed by the processor.

A vehicle plug for transmitting power and signals between a vehicle and a trailer includes a power conductor and one or more video signal conductors. The power conductor is configured to provide power to one or more electrical components of the trailer, the one or more electrical components of the trailer includes one or more video cameras. The one or more video signal conductors are configured to receive video signals from the one or more video cameras of the trailer.

A mirror substitute device for a vehicle has at least one camera designed to cover at least a part of the surroundings of the vehicle and to provide a corresponding image signal, an image processing device coupled to the camera and designed to process the image signal and to output a processed image signal, and at least one display device designed to display the processed image signal.

A system for automatically displaying image data when a vehicle is located on an on-ramp to a roadway includes one or more processors, left and right vehicle side cameras, a display, and one or more memory modules. The one or more memory modules store logic that cause the system to: determine, based on the location signal output by the one or more vehicle location sensors, whether a vehicle is on the on-ramp to merge on to the roadway; determine a direction of merging, and display image data on the display. Image data from the left vehicle side camera is displayed when it is determined that the direction of merging is to a left side of the vehicle. Image data from the right vehicle side camera is displayed when it is determined that the direction of merging is to a right side of the vehicle.

An electronic mirror apparatus includes an imaging part mounted at one-side or each of both-side surfaces of a vehicle and taking an image in a rear-and-side directions of the vehicle; and a display part mounted in the vehicle interior and displaying an image taken by the imaging part or an image acquired through a predetermined transform process on the image taken by the imaging part. The display part displays the image corresponding to an imaging range that is different between a case where a shift position of the vehicle is a forward position and a case where the shift position is a reverse position.

A vehicle includes a proximity sensor that senses a distance to objects located to at least one side of the vehicle, a camera mounted at the front of the vehicle, a display for displaying video from the camera, and processing circuitry that detects a transition of the vehicle from surroundings of the vehicle in which at least one object located to the side of the vehicle is within a predetermined proximity threshold distance to surrounding of the vehicle in which no objects are located to the side of the vehicle within the predetermined proximity threshold distance, and in response to determining that, at least, the proximity sensor has detected the transition, the processing circuitry is configured to display video from the camera on the display of the vehicle. Additional criteria for displaying the video can include vehicle speed, distance traveled prior to the transition, duration for which the state prior to the transition was maintained, and the state of the vehicle's turn signal.