A dual-function imaging system may comprise an imager comprising a lens, the lens having an inner region and an outer region surrounding the inner region; an image processor in communication with the imager; a first video display element in communication with the image processor; and a second video display element in communication with the image processor. The lens may have a first effective magnification level in the inner region and a second effective magnification level in the outer region.

An apparatus includes a visual display to be viewed by a vehicle occupant. At least one drone includes a camera. A controller is configured to receive images from the camera on the at least one drone and generate an overhead view of the vehicle based on the images received from the at least one drone and display the overhead view on the visual display.

A vehicular vision system includes a camera disposed at a front portion of a vehicle, a display screen and a processor for processing image data captured by the camera. The processor performs first, second and third image manipulations on first, second and third portions of the image data to generate first, second and third region manipulated image data. The display screen displays first, second and third images derived from the manipulated image data at respective display regions. The displayed images are discontinuous at a first seam between first and second display regions and discontinuous at a second seam between first and third display regions. An object present in first and second regions of the view of the camera is displayed as discontinuous at the first seam and an object present in the first and third regions of the view of the camera is displayed as discontinuous at the second seam.

For driver assistance for a combination (8) with a motor vehicle (9) and a trailer (10), a first camera image (19) and a second camera image (20) are generated. A combined image (21) is generated by means of a computing unit (13) by superimposing the camera images (19, 20) such that the second camera image (20) covers a subsection of the first camera image (19), wherein a hitch angle (14) of the combination (8) is determined by means of the computing unit (13). State data of the combination (8) are determined by means of a sensor system (17) and it is determined whether the combination (8) moves forward or backward. The hitch angle (14) is determined based on the state data, if the combination (8) moves forward and based on a change of time-dependent image data, if the combination moves backward. A position of the subsection is determined depending on the hitch angle (14).

Method and control unit for reducing a blind spot created by a field of view adjustment of a vehicle comprised presentational device intended to display objects outside a driver's direct field of vision. The method comprises: detecting the blind spot of the presentational device, based on signals received from at least one first sensor associated with the presentational device; adjusting at least one second sensor, not associated with the presentational device, in order to cover at least a part of the detected blind spot; and outputting information captured by the adjusted at least one second sensor.

A vehicle surrounding monitor apparatus comprises a camera which takes images of a view around an own vehicle. The vehicle surrounding monitor apparatus stores the images of the view around the own vehicle taken by the camera, produces a current image under a floor of the own vehicle as an underfloor image by using the stored images, and displays the produced underfloor image on a display. The vehicle surrounding monitor apparatus terminates displaying the underfloor image on the display when time for which the own vehicle has stopped reaches a predetermined first time.

A vision system for a motor vehicle and a method for providing information to a driver of a motor vehicle, where the system includes at least one video camera, including a lens, adapted and configured to be mounted on a side of the vehicle with the lens facing forward, the lens having an angle of view that provides a field of view for allowing capture, simultaneously, of images of a view alongside the vehicle and of at least part of the side of the vehicle from the rear towards the front of the vehicle, and a processor coupled to the at least one video camera, the processor adapted and configured to process the captured images and provide processed images for display on a monitor and/or vehicle orientation information to a computerized vehicle operation system.

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.

An ECU controls an in/out motor so as to, interlockingly with turning of a vehicle, change a viewing range of a periphery of the vehicle with respect to a vehicle occupant. The ECU controls the in/out motor such that the viewing range returns to an original viewing range by a time of an end of turning.

An electronic mirror system comprising: an imaging portion that captures an image around a vehicle, and outputs the image to an image display control apparatus; and a display portion that displays an image received from the image display control apparatus. The image display control apparatus comprising: a shift amount calculation portion that calculates a shift amount of an object image that shows an object within an image; a following speed determination portion that determines a following speed of an additional image for the object image; an elapsed time calculation portion that calculates the elapsed time; a shift amount determination portion that determines a shift amount of the additional image; an additional image synthesis portion that synthesizes the additional image to the object image; and a display controller that allows the display portion to display a synthetic image.