A shovel includes a lower traveling body, an upper rotating body rotatably mounted on the lower traveling body, a cab mounted on the upper rotating body, a left monitor mounted on a left pillar inside the cab, a right monitor mounted on a right pillar inside the cab, a left camera configured to capture an image of an area on a left side of the upper rotating body, a right camera configured to capture an image of an area on a right side of the upper rotating body, and a controller configured to control both the left monitor and the right monitor. The controller is configured to cause the left monitor to continuously display a mirror image generated from the image captured by the left camera, and to cause the right monitor to continuously display a mirror image generated from the image captured by the right camera.

A display device includes a light collector including a camera unit having a camera and a window unit having a window, an optical unit that controls a path of light received from the window unit, and a transparent display panel including at least one pixel area that displays an image based on an image captured by the camera unit and at least one transmissive area that displays an image received from the optical unit.

An interior rear view mirror assembly for a vehicle includes a mirror housing rotatably attached to a housing holder which is adapted to be attached to an interior of the vehicle, the mirror housing including a first rear view side to which a reflective mirror element is attached, and a second rear view side to which a display device with a display screen is attached to, where a camera is connected to the display device establishing a display system to provide an image to the display screen; and an actuator unit configured to automatically rotate the mirror housing to the first or second rear view side. A vehicle and a method may be used to operate the interior rear view mirror assembly.

A vehicular camera assembly includes a camera housing having a front housing portion and a rear housing portion. The front housing portion accommodates a lens. A first printed circuit board (PCB) is disposed at the front housing portion, with an imager disposed at a front side of the first PCB and a first electrical connector disposed at a rear side of the first PCB. A second PCB has a second electrical connector disposed at a front side. Circuitry of the second PCB is electrically connected to circuitry of the first PCB via electrical connection of the first and second electrical connectors. A plurality of terminal pins has a first end interior the camera housing and a second end at a connector portion of the rear housing portion. The connector portion is configured for connecting to a vehicle wiring connector when the vehicular camera assembly is installed at a vehicle.

The surrounding vehicle display system comprises an object detection device detecting an object in surroundings of a vehicle, an electronic control unit, and a display device. The electronic control unit is configured to generate an object mark based on an output of the object detection device and identify the object mark. The display device displays the surrounding vehicle as a vehicle icon when the object mark is identified as a surrounding vehicle by the electronic control unit. The electronic control unit is configured to determine a position of the vehicle icon with respect to the vehicle on the display device and offset a center position of the vehicle icon from a center position of the object mark identified as the surrounding vehicle based on a predetermined size of the vehicle icon.

A left infrared camera module provided in a vehicle includes: a left infrared emitting unit configured to emit infrared rays toward an outside, and a left infrared camera configured to acquire infrared image data indicating a surrounding environment of the vehicle. The left infrared emitting unit and the left infrared camera are mounted on a left C-pillar of the vehicle.

A method of aligning a tow vehicle with a trailer positioned behind the tow vehicle is provided. The method includes determining a point cloud map of a rear environment of the tow vehicle. The rear environment includes the trailer. The method also includes determining a front face plane of the trailer based on the point cloud map. The method also includes determining a normal line of the front face plane. The method also includes determining a path from the tow vehicle to the trailer such that a fore-aft axis of the tow vehicle is aligned with the normal line of the front face plane.

The invention refers to a set of rear view assemblies (10) for a vehicle (20) comprising: at least one first rear view assembly (1) to be mounted to a driver side (21) of the vehicle (20) to observe traffic conditions behind on the driver side (21), comprising a first base assembly (1a) and a first head assembly (1b) mounted on the first base assembly (1a), where the first head assembly comprises a mirror element (4) having a first size being a minimum size still fulfilling the legal requirements for provided a mirror-based field of view (FOV-21) on the driver side (21); and at least one second rear view assembly (2) to be mounted on a passenger side (22) of the vehicle (20) to observe traffic conditions behind on the passenger side (22), comprising a second base assembly (2a) and a second head assembly (2b) mounted on the second base assembly (2a), where the second head assembly (2b) comprises a mirror element (4) having a second size being the same minimum size as one of the first head assembly (1b) of the first rear view assembly (1), and a vision system (3) at least comprising at least one vision sensor (31) and a display (32), where the vision sensor (31) is arranged in the second rear view assembly (2) to record an image of the traffic conditions behind on the passenger side (22) to be displayed to a driver (5) by the display (32) with a field of view adapted to meet the legal requirements for the mirror-based field of view (FOV-22) on the passenger side (21) regardless on the reduced size of the second head assembly (2b) of the second rear view assembly (2), wherein the first rear view assembly (1) on the driver side (21) and the second rear view assembly (2) on the passenger side (22) are reduced to a size adapted to the smaller field of view (FOV-21) on the driver side (21) resulting in smaller rear view assemblies (1, 2) having to carry smaller mirror elements (4).

A rearview device for a motor vehicle includes a moveable head assembly, an actuator assembly having a fixed part and a moveable part, the moveable part being attached to the head assembly, a motor cradle configured to attach the actuator assembly to the moveable head assembly. A method of assembling a rearview device comprises providing the rearview device and attaching the actuator assembly to the moveable head assembly using the motor cradle.

A vehicle display control device includes a first image acquisition unit that acquires a first image by a first camera unit, a second image acquisition unit that acquires a second image by a second camera unit, a bird's-eye view image generation unit that generates a bird's-eye view image where a virtual vehicle image is synthesized at a center thereof based on the second image, a detection unit that performs an object recognition processing on the first image to detect a warning object, a direction calculation unit that calculates a direction of the warning object from the virtual vehicle image on a position of the warning object, and a display controller that displays the first image on a first monitor, and the bird's-eye view image and the direction of the warning object therein on a second monitor based on a position of the first camera unit in the vehicle image.