A backward accident protection (BAP) system includes a video camera attached to the rear windshield of a vehicle. A microcomputer analyzes the camera image to assess the risk of a rear impacts. Upon detection of a potential rear impact, the BAP system initiates actions to reduce the severity of the potential rear impact.

A vehicular vision system includes a front camera and a rear camera disposed at a vehicle and each viewing exterior of the vehicle. Each of the cameras connects with a control via a respective mono coaxial cable. The respective mono coaxial cables carry control data from the control to the respective cameras and carry image data captured by the respective cameras to the control. The control generates an output provided to a video display device of the vehicle. The video display device includes a video display screen viewable by a driver of the vehicle. During a reversing maneuver of the vehicle, the video display screen displays video images of an area rearward the vehicle derived from image data captured by the rear camera and carried to the control by the respective mono coaxial cable.

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 electronic mirror device performs display by switching between an image captured by a rear camera which is mounted on a rear part of a vehicle and captures an image of an area behind the vehicle, and an image captured by a mirror camera which is mounted near a position where a rearview mirror is mounted and captures an image of an area behind the vehicle. This electronic mirror device includes an image display unit that performs display by switching between an image captured by the rear camera and an image captured by the mirror camera, and a controller that controls the image display unit. The controller switches the display on the image display unit between the image captured by the rear camera and the image captured by the mirror camera, when an image of an object of interest captured by the rear camera coincides with an image of the object of interest captured by the mirror camera.

Vehicle (1) comprising:—a driver compartment (4) with driving seat (8),—a door pivotally mounted on a lateral frame along a door swept, the door comprising a lateral window,—a viewing system (25) comprising a wing (28) comprising a first end (28a) mounted on the lateral frame (19) and a second end (28b), and at least one camera (26) mounted on the wing (28) so as to acquire a lateral rear view of the vehicle (1),—a side clearance device (35) comprising a deflector (37) presenting an extended configuration in which said deflector (37) is directly visible from the driving seat (8) through the lateral window so as to enable a driver (9) to locate the second end (28b) of the wing (28), the deflector (37) being movable between the extended configuration and a retracted configuration in which the deflector (37) is arranged outside of the door swept.

A computer includes a processor and a memory storing instructions executable by the processor to detect an object in data received from a rear-facing radar on a vehicle and activate an alarm in response to the object moving through a predesignated region behind the vehicle at a speed below a threshold speed or for a duration above a threshold time.

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 rear module for a vehicle includes a crossmember that extends along a transverse direction and is connected to the vehicle body and a bumper connected to the crossmember. The bumper includes an aperture. The rear module further includes a reversing camera that protrudes through the bumper, and a first impact element and a second impact element arranged on the bumper to a respective first side and a respective second side of the reversing camera and at a lateral spacing, in the transverse direction, from the reversing camera. The first impact element and the second impact element protrude, in the longitudinal direction, beyond the reversing camera and/or the bumper.

A vehicle periphery monitoring device includes a plurality of sensors including a rear camera, a rear right-side camera, and a rear left-side camera, a display unit that is provided inside a vehicle cabin, memory, and a processor that is coupled to the memory. The processor is configured so as to acquire a rear image that includes a first image of a vehicle rear side acquired by the rear camera, a second image of a vehicle rear right-side acquired by the rear right-side camera, and a third image of a vehicle rear left-side acquired by the rear left-side camera, acquire from the plurality of sensors relative positions of a target that is present in areas including the vehicle rear side, the vehicle rear right-side, and the vehicle rear left-side relative to a host vehicle, determine whether or not the acquired relative positions of the target are mutually consistent with each other in the plurality of sensors, display a single composite image that is created by combining the first image, the second image, and the third image at the display unit in a case in which it is determined that the relative positions of the target are mutually consistent with each other, and display the first image, the second image, and the third image individually and adjacently to each other on the display unit in a case in which it is determined that the relative positions of the target are not mutually consistent with each other.

A display device for a vehicle, including: a rear imaging section that captures a rear image; a rear lateral imaging section that captures rear lateral images; and a control section that generates a combined image in which a rear processed image obtained by processing the rear image with a first parameter, and rear lateral processed images obtained by processing rear lateral images with a second parameter, are combined, wherein the control section further identifies an object existing in the rear image or the rear lateral images; acquires relative information including relative position and relative speed of the object with respect to the vehicle, and blind spot regions of the combined image; and, based thereon, if the object will disappear from the combined image due to entering into the blind spot regions, changes the blind spot regions by adjusting the first and second parameters.