A vision display system for a vehicle includes a rear backup camera, a driver side camera, a passenger side camera, a front camera, and a display system including a video display screen. Rear backup video images derived from image data captured by the rear backup camera may be displayed by the video display screen for no more than ten seconds after shifting of the vehicle transmission of the vehicle out of reverse gear. Upon the engine of the vehicle being first started after initial ignition on of the vehicle, priority may be given to display by the video display screen of rear backup video images. Within two seconds after shifting of the vehicle transmission of the vehicle into reverse gear, rear backup video images may be displayed by the video display screen.

A vehicle mounted sensor assembly includes a frame and a cover connected to the base. When assembled, the frame and the cover define a volume that is divided between a first cavity and a second cavity. A sensor is disposed in the first cavity and one or more antennas are disposed in the second cavity.

A vehicle mounted sensor assembly includes a frame and a cover connected to the base. When assembled, the frame and the cover define a volume that is divided between a first cavity and a second cavity. A sensor is disposed in the first cavity and one or more antennas are disposed in the second cavity.

A method is provided for determining a position for a camera on an outer skin of a vehicle, the position being determined such that the camera can detect an object at a visual reference point behind the vehicle. The method identifies a lateral surface which, in an initial position, is parallel to an XZ plane of the vehicle at a lateral distance from a central x-axis of the vehicle, the lateral distance depending on a maximum width of the vehicle. The method identifies an axis of rotation for the lateral surface which is parallel to a z-axis of the vehicle and which extends through the visual reference point. The method determines a point of intersection of the lateral surface rotated, starting from the initial position, about the axis of rotation with the outer skin of the vehicle. The method determines the position for the camera based on the point of intersection.

A method is provided for determining a position for a camera on an outer skin of a vehicle, the position being determined such that the camera can detect an object at a visual reference point behind the vehicle. The method identifies a lateral surface which, in an initial position, is parallel to an XZ plane of the vehicle at a lateral distance from a central x-axis of the vehicle, the lateral distance depending on a maximum width of the vehicle. The method identifies an axis of rotation for the lateral surface which is parallel to a z-axis of the vehicle and which extends through the visual reference point. The method determines a point of intersection of the lateral surface rotated, starting from the initial position, about the axis of rotation with the outer skin of the vehicle. The method determines the position for the camera based on the point of intersection.

A recessed portion positioned on a vehicle rear side with respect to a lens of a camera and recessed in an inner side direction from an outer surface of a mirror housing is provided on the mirror housing. A flow rectifying surface, which forms a flow of traveling wind toward the recessed portion, is provided on the mirror housing.

A recessed portion positioned on a vehicle rear side with respect to a lens of a camera and recessed in an inner side direction from an outer surface of a mirror housing is provided on the mirror housing. A flow rectifying surface, which forms a flow of traveling wind toward the recessed portion, is provided on the mirror housing.

A method for identifying a cause of blockage in a sequence of images provided by a camera of a vehicle, the method comprising iteratively: S10) acquiring an image of the camera; successively acquired images forming a sequence of images; S20) detecting a blockage in last images of the sequence of images; S60) determining whether it is day-time or night-time based on time information; if it is determined that it is night-time: S82) determining whether toggling front light(s) of the vehicle on/off causes a change in images acquired by the camera; and S84) in this case, determining that for the current iteration, the cause of the blockage is presumably the road being dark. A computer program for performing said method, a computer-readable recording medium containing such computer program, a driving assistance system capable of executing said method.

A method for identifying a cause of blockage in a sequence of images provided by a camera of a vehicle, the method comprising iteratively: S10) acquiring an image of the camera; successively acquired images forming a sequence of images; S20) detecting a blockage in last images of the sequence of images; S60) determining whether it is day-time or night-time based on time information; if it is determined that it is night-time: S82) determining whether toggling front light(s) of the vehicle on/off causes a change in images acquired by the camera; and S84) in this case, determining that for the current iteration, the cause of the blockage is presumably the road being dark. A computer program for performing said method, a computer-readable recording medium containing such computer program, a driving assistance system capable of executing said method.

A vehicle is configured to transport a passenger through autonomous travel. The vehicle includes an in-vehicle camera configured to image the passenger to generate an image, a camera controller configured to control the in-vehicle camera, and a passenger information detection unit configured to detect information about the passenger. The passenger information detection unit measures the number of passengers and the camera controller stops an operation of the in-vehicle camera in a case where the number of passengers is one.