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.

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.

An assist method for coupling a motor vehicle to a trailer, wherein the motor vehicle includes a trailer coupling, at least one camera, a display, and an electronic unit, and wherein the trailer includes a tow bar for the trailer coupling. The assist method captures a first image of at least one tow bar of a trailer by the camera, displays the first image on the display, selects a first region in the first image in which the tow bar is located, enlarges the selected first region to produce a second image, displays the second image on the display, selects a second region in the second image in which the tow bar is located, and determines a trajectory of the motor vehicle for coupling the trailer assuming that the tow bar is located in the second region.

A view system for a vehicle (1) with a tractor (2) and a trailer (3). The view system has a capture unit (10) with an image sensor (12) for capturing image data of an area of view, around the vehicle, a processing unit (20) for processing the image data, and a reproduction unit (30) for reproducing at least one first image section (410) and one second image section (420) of the area of view (40) captured by the capture unit (10). The processing unit provides different resolutions of image data depending on the position of the tractor with respect to the trailer.

Provided is an input unit to which input signals are inputted, the input signals including signals indicating operating states of switches used for operating the electronic mirror and used for selecting a display mode from among the plurality of display modes to be displayed by the electronic mirror; a storage unit that together with prioritizing and storing each of a plurality of display modes in a hierarchical structure, stores mode setting conditions that are conditions for setting each display mode; a determination unit for determining whether or not the mode setting conditions are satisfied for each of the plurality of display modes based on the input signals; and a setting unit that, of the plurality of display modes, sets a display mode from among the display modes for which the mode setting conditions are satisfied, as a display mode to be displayed on the electronic mirror.

A system for displaying vehicle driving information may include: first and second image acquisition devices configured to capture an image of a first side on which a driver seat is located and an image of a second side which is the opposite side of the first side, respectively; first and second display devices configured to display the captured images of the first and second image acquisition devices, respectively; first and second BSD devices and configured to sense side-rear vehicle information; and a control device configured to recognize the location and vehicle distance of the side-rear vehicle by analyzing the side-rear vehicle information detected by the first and second BSD devices, determine whether to issue a BSD warning, and control BSD warning icons of the ego vehicle and the side-rear vehicle to be displayed as an OSD of the images displayed on the first and second display devices.

A vehicular vision system includes first and second cameras disposed at a vehicle and having respective overlapping fields of view that include a road surface of a road along which the vehicle is traveling. Image data captured by the cameras is provided to an image processor and is processed to determine relative movement of a road feature present in the captured image data. The determined movement of the road feature relative to the vehicle in first image data captured by the first camera is compared to the determined movement of the road feature relative to the vehicle in second image data captured by the second camera, and at least a rotational offset of the second camera at the vehicle relative to the first camera at the vehicle is determined and the image data are remapped to at least partially accommodate misalignment of the second camera relative to the first camera.

A camera monitoring system for motor vehicles is provided. An image capturing device is provided on a mounting assembly of the vehicle for an exterior field of view (FOV) of the vehicle extending sideward and rearward outside the vehicle and encompassing a portion of the exterior part of the vehicle. An electronic control unit (ECU) is connected to the image capturing device to obtain a captured image. An electronic display device is connected to the ECU and is located inside the vehicle and to be used by a driver. A gesture detector is configured to obtain at least one position of at least one part of the driver's body. The ECU is configured to adjust the FOV based on the obtained position and the display device is configured to display the adjusted FOV in a displayed image region, which can be moved within the captured image.

A work vehicle display system utilized in piloting a work vehicle includes a display device having a display screen, a context camera mounted to the work vehicle and positioned to capture a context camera feed of the work vehicle's exterior environment, and a controller architecture. The controller architecture is configured to: (i) receive the context camera feed from the context camera; (ii) generate a visually-manipulated context view utilizing the context camera feed; and (iii) output the visually-manipulated context view to the display device for presentation on the display screen. In the process of generating the visually-manipulated context view, the controller architecture applies a dynamic distortion-perspective (D/P) modification effect to the context camera feed, while gradually adjusting a parameter of the dynamic D/P modification effect in response to changes in operator viewing preferences or in response to changes in a current operating condition of the work vehicle.

A system of rear view assemblies for a vehicle includes at least one first rear view assembly mounted to a driver side of the vehicle to observe traffic conditions behind the driver side, at least one second rear view assembly mounted on a passenger side of the vehicle to observe traffic conditions behind the passenger side, and a vision system. A vehicle including such a system is also described.