A vehicular vision system includes a vehicle camera docking station disposed at a vehicle, a trailer camera docking station disposed at a rear of a trailer, and a camera operable to capture image data and to communicate captured image data to a data receiving device at the vehicle. When the trailer is not hitched to the vehicle, the camera is disposed at the vehicle camera docking station so as to have a field of view rearward of the vehicle. When the trailer is hitched to the vehicle, the camera is removed from the vehicle camera docking station and disposed at the trailer camera docking station so as to have a field of view rearward of the trailer. The camera captures image data and communicates captured image data to the data receiving device, which receives the communicated image data. A display device displays video images derived from the received image data.

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 vehicular multi-camera vision system includes a plurality of exterior viewing vehicle cameras disposed at a vehicle, a trailer camera disposed at a rear of a trailer and viewing rearward, an ECU and a display device in the vehicle. With the trailer not hitched to the vehicle and during a driving maneuver of the vehicle, image data captured by the vehicle cameras is provided to the ECU and the display device displays video images generated by the ECU and derived from image data captured by the vehicle cameras. With the trailer hitched to the vehicle and during a driving maneuver of the vehicle towing the trailer, image data captured by the trailer camera and the vehicle cameras is provided to the ECU and the display device displays video images generated by the ECU and derived from image data captured by the trailer camera and side viewing vehicle cameras.

Devices, systems and methods for operating a rear-facing perception system for vehicles are described. An exemplary rear-facing perception system contains two corner units and a center unit, with each of the two corner units and the center unit including a camera module and a dual-band transceiver. A method for operating the rear-facing perception system includes pairing with a control unit by communicating, using the dual-band transceiver, over at least a first frequency band, transmitting a first trigger signal to the two corner units over a second frequency band non-overlapping with the first frequency band, and switching to an active mode. In an example, the first trigger signal causes the two corner units to switch to the active mode, which includes orienting the camera modules on the center unit and the two corner units to provide an unobstructed view of an area around a rear of the vehicle.

A display system includes a recognizer configured to recognize a surrounding situation of a vehicle, a display configured to display images, and a display controller configured to cause the display to display an image representing a road shape around the vehicle recognized by the recognizer, wherein, when a lane in which the vehicle can travel in the same direction as a travel direction of the vehicle is added, the display controller causes the display to display an image about the added lane outside the image representing the road shape on the side on which the lane is added before the display is caused to display an image representing a shape of the added lane.

Systems and methods are provided for using video/still images captured by continuously recording optical sensors mounted on waste collection vehicles used in in the waste collection, disposal and recycling industry for operational and customer service related purposes. Optical sensors are integrated into the in-cab monitor as well as the onboard computer, digital video recorder and other external devices.

A traffic light display assembly includes a control panel that is positioned on a dashboard of a semi tractor. The control panel includes a camera for viewing a traffic light which the semi tractor is facing. A display unit is removably coupled to a back side of a semi trailer to be visible to traffic behind the semi trailer. The display unit is in remote communication with the control panel. Moreover, the display unit has a plurality of light emitters thereon each being associated with a respective light on the traffic light at which the semi tractor facing. Each of the light emitters is turned on when the associated light on the traffic light is turned on to communicate the status of the traffic light to the traffic behind the semi trailer.

An imaging and display system for use in a vehicle pulling a trailer, the system including: a trailer camera mounted on the trailer such that the camera is oriented to receive images from a first field of view having a horizontal angle and a vertical angle where the vertical angle is greater than the horizontal angle; an image processor for creating a back-up image and a rearward image from an image captured by the camera, the back-up image corresponding to a second field of view cropped from the lowest portion of the first field of view and the rearward image corresponding to a third field of view cropped from a portion of the first field of view above the lowest portion, the third field of view having a horizontal angle and a vertical angle where the horizontal angle is greater than the vertical angle.

A communication system for vehicles includes a camera disposed at a first vehicle and having a field of view exterior of the first vehicle. The camera captures image data. A first communication device disposed at the first vehicle wirelessly transmits image data captured by the camera. A second communication device disposed at a second vehicle receives the transmitted captured image data from the first communication device. At least one of (i) an image processor disposed at the second vehicle processes the received transmitted captured image data for a driver assistance system of the second vehicle and (ii) a display of the second vehicle displays images derived from the received transmitted captured image data for viewing by a driver of the second vehicle.

Devices, systems and methods for operating a rear-facing perception system for vehicles are described. An exemplary rear-facing perception system contains two corner units and a center unit, with each of the two corner units and the center unit including a camera module and a dual-band transceiver. A method for operating the rear-facing perception system includes pairing with a control unit by communicating, using the dual-band transceiver, over at least a first frequency band, transmitting a first trigger signal to the two corner units over a second frequency band non-overlapping with the first frequency band, and switching to an active mode. In an example, the first trigger signal causes the two corner units to switch to the active mode, which includes orienting the camera modules on the center unit and the two corner units to provide an unobstructed view of an area around a rear of the vehicle.