A camera system for a trailer that cooperates with a tarping system of the trailer to capture images during loading and unloading. The camera transmits the images to a display. A driver may watch the display to monitor loading and unloading. The camera system maintains a camera of the camera system positioned to capture images of an interior of the trailer regardless of the operation of the tarping system. The camera system generally includes an arm member, a pivot structure connected to the arm member, a camera connected to the arm member, and a weight connected to the arm member. Responsive to a force of gravity the camera remains oriented upward to capture images of the interior of the trailer during loading and unloading.

A vehicle moves in relation to the surroundings along a movement direction. The vehicle includes a first and a second camera. The first camera is arranged in front of the second camera along the movement direction. A method for scanning the surroundings from the vehicle includes scanning a first image by the first camera; scanning a second image by the second camera; and combining the first and the second image to form an overall image. The second image is scanned with a time delay in relation to the first image, so that an offset of locations at which the images are scanned is less than an offset of the cameras on board the vehicle.

A display system for a vehicle includes a first camera in connection with the vehicle. The first camera outputs unprocessed image data. A second camera outputs a first processed image data. A display controller is in communication with the first camera via a conductive interface and the second camera via a wireless interface. The controller is configured to receive the unprocessed image data from the first camera and receive the first processed image data from the second camera. The controller further generates second processed image data from the unprocessed image data and selectively outputs the first processed image data and the second processed image data to a vehicle display device.

A technique for rendering an under-vehicle view including obtaining a first location of a vehicle, the vehicle having a set of cameras disposed about the vehicle, capturing a set of images; storing images of the set of images in a memory, wherein the images are associated with a time the images were captured, moving the vehicle to a second location, obtaining the second location of the vehicle, determining an amount of time for moving the vehicle from the first location to the second location, generating a set of motion data, the motion data indicating a relationship between the second location of the vehicle and the first location of the vehicle, obtaining one or more stored images from the memory based on the determined amount of time, rendering a view under the vehicle based on the one or more stored images and set of motion data, and outputting the rendered view.

In a first case a trimmed image generating section carries out trimming such that respective lateral direction lengths of a rear processed image and rear lateral processed images in the combined image are equal, and in a second case in which the trimmed image generating section judges that there is information that is included in the images of the first overlapping regions and is not included in the images of the second overlapping regions and information that should be included in the combined image, the trimmed image generating section carries out trimming such that the information that should be included in the combined image remains in the rear lateral processed images, and, as compared with the first case, the lateral direction length of the rear processed image in the combined image is short, and the lateral direction lengths of the rear lateral processed images in the combined image are long.

Arrangements herein relate to a method and system for selectively displaying surroundings of an autonomous vehicle. The system can include a display to display a plurality of images in which some of the images are images of an environment external to the autonomous vehicle and are images unrelated to the environment external. The system can include cameras to capture the images of the environment external. The system can further include a processor that can be configured to detect a handover event associated with the operation of the vehicle. In response to the detection of the handover event and if the display is displaying images unrelated to the environment external, the processor can also cause the display to display images of the environment external in the place of the images unrelated to the environment external.

A vehicle-mounted alert system includes display devices equipped to a vehicle, a sight line detection device detecting driver's sight line, a surrounding monitoring device detecting a presence of an object near the vehicle and a direction of the object with respect to the vehicle, and an alert control device controlling the display devices to display an alert image for informing the driver of the presence of the object detected by the surrounding monitoring device. The alert control device controls the display device located in a direction of the sight line of the driver to display the alert image, and then, controls the display devices so that the alert image successively moves from the display device located in the direction of the sight line of the driver to the display device determined based on the direction of the object detected by the surrounding monitoring device.

A working vehicle periphery monitoring system includes: image capturing devices attached to a working vehicle with a vessel and capturing the periphery of the working vehicle to output image information; a bird's eye image synthesizing unit synthesizing the image information to generate a bird's eye image information for displaying bird's eye images of the working vehicle and the periphery thereof; and a display control unit displaying at least one of a first bird's eye image obtained by superimposing a first vessel image including the vessel other than a part of the vessel at a rear side of the working vehicle on an area of the working vehicle in the bird's eye image and a second bird's eye image obtained by superimposing a second vessel image including all of the vessel on the area.

A lighting assembly for a vehicle is provided herein. The lighting assembly includes first and second sets of light sources disposed on a bumper of the vehicle. A photoluminescent structure is disposed on the lighting assembly and configured to luminesce in response to excitation by the first or second sets of light sources. A detection system is configured to detect an object disposed proximately to the vehicle. The first or second set of light sources illuminate upon the detection of the object.

A vehicle occupant viewing system and a corresponding method for displaying a vehicle occupant on an image display unit. The system may comprise one or more vehicle interior cameras for obtaining occupant images of one or more occupants in rear seats of the vehicle. The system may include two vehicle interior cameras, one in a forward facing orientation and another in a rear facing orientation, which can capture occupant images of occupants in forward facing positions and occupants in rear facing positions such as infants in car seats. The system may also include one or more modular vehicle interior cameras that are moveable between various orientations in order to capture occupant images of either forward or rear facing passengers. Adjustments can be made to display the occupant images to the driver in a more intuitive arrangement.