The present disclosure relates to a display system (1) for generating a composite view of a region behind a vehicle (V) towing a trailer (T). A first camera (C1) is provided for outputting first image data corresponding to a first image (IMG1), the first camera (C1) being configured to be mounted in a rear-facing orientation to the vehicle (V). A second camera (C2) is provided for outputting second image data corresponding to a second image (IMG2), the second camera (C2) being configured to be mounted in a rear-facing orientation to the trailer (T). An image processor (5) receives the first image data and said second image data. The image processor (5) is configured to combine said first image data and said second image data to generate composite image data corresponding to a composite image (IMG3). The present disclosure also relates to a corresponding method of generating a composite image (IMG3), and to a rig made up of a vehicle (V) and a trailer (T).

Leading and trailing electrified vehicles are coupled together in a towing arrangement for in-flight transfer of an electrical charge between their battery systems. With the vehicles connected by a towing device, a parking maneuver is initiated in which the trailing vehicle leads the leading vehicle. For the parking maneuver, one of the vehicles is designated (e.g., automatically or by driver agreement) to be an active steering vehicle and the other vehicle to be a passive steering vehicle. At least the passive steering vehicle comprises an electrically-controlled steering actuator. During movement, a turning (e.g., steering angle) of the active steering vehicle is monitored. Based on the turning of the active steering vehicle, an assistive steering angle is determined for the passive steering vehicle. The electrically-controlled steering actuator is commanded according to the assistive steering angle. The parking maneuver may be reverse or forward.

In a tilt parking mode, “a target parking position” can be accurately determined without changing a camera tilt angle and an HMI display range, and can be notified to a driver, so that the usability can be improved. A parking support device includes an external field recognition unit such as a camera and a sonar, which recognizes an external field, an information holding unit which holds information of a parking frame line recognized by the external field recognition unit, a parking region extraction unit which extracts a parking region from information of the parking frame line, a parking position determination unit which determines a target parking position from the parking region, and a path calculation unit which calculates a parking path from a current position of an own vehicle up to the target parking position. In a case where part of the parking frame line is not recognized by the camera, the target parking position is defined on the basis of lines connecting an end point of the parking frame line on a rear side of the own vehicle, a virtually extending line of the parking frame line on a front side of the own vehicle, and a point intersecting with the virtual line on a front side of the vehicle from the end point of the parking frame line on the rear side of the own vehicle.

An image processing apparatus is provided. An image photographed by a camera that photographs the surroundings of the vehicle is received. An overhead image, a vehicle travel direction image, and a vehicle lateral side image corresponding to a vehicle movement direction which is either left or right of the vehicle is generated based on the image. The generated image is displayed on a display unit. For example, a display image is generated or updated in accordance with a travel direction of the vehicle and direction-of-rotation information of a steering wheel. In a case where the vehicle is backed counter-clockwise, the overhead image, the vehicle rear image, and a vehicle left side image are generated and displayed. In a case where the vehicle is backed clockwise, the overhead image, the vehicle rear image, and a vehicle right side image are generated and displayed.

A vehicle assembly system includes a vehicle chassis of a vehicle; at least one object sensor mounted to the vehicle chassis, where the at least one object sensor generates sensor data based on at least one detected object; a vehicle controller mounted to the vehicle chassis and configured to receive the sensor data from the at least one object sensor, where, during assembly, the vehicle controller is configured with production control software that enables the vehicle controller to generate production object data from the sensor data, monitor for a safety event based on the production object data, and generate a safety event signal in response to detecting the safety event; and a safety controller configured to receive the safety event signal from the vehicle controller and alter a movement of a surveilled machine corresponding to the safety event.

Disclosed are systems and methods for projecting virtual parking lines in alignment with actual parking lines to facilitate parking within a parking stall defined by the actual parking lines to prevent unnecessary damage to vehicles in an area where the actual parking lines may not exist or be visible. The system identifies the location of the actual parking lines within a defined parking area based on previously recorded actual parking line data as well as localization of the vehicle within the defined parking area relative to the nearby landmarks. Virtual parking lines are generated that correspond with the location of the actual parking lines and are projected in alignment with the actual parking lines to facilitate parking.

A method of operating an immersive display includes obtaining first images of environment in a first region in front of the immersive display, obtaining second images of environment in a second region outside the first region, which second region is not in front of the immersive display, displaying the first images of the environment on a first area of at least one display of the immersive display to provide a field of view of the environment in front of the immersive display, and displaying the second images of the environment in the second region on a second area of the at least one display to provide images outside the field of view of the environment in front of the immersive display. The first area is delineated from the second area.

A driver assistance device according to an embodiment includes a coupling angle acquirer that acquires a coupling angle between a towing vehicle and a towed vehicle coupled to the towing vehicle; and a notifier that issues a given notification in the towing vehicle when the towing vehicle is driven with the towing vehicle and the towed vehicle differing in orientation at a given value or more based on the coupling angle, the towing vehicle moves in a given distance or less while maintaining a steering angle, and the steering angle of the towing vehicle enables the towing vehicle and the towed vehicle to be placed in a serial state with the towing vehicle and the towed vehicle substantially matching with each other in orientation.

The present disclosure provides a method, system, and apparatus for processing parking and a vehicle controller, and relates to the field of intelligent transportation technology, specifically to the field of automated parking technology. The method is executed by a parking system deployed on a vehicle controller, the parking system including a perception module and other modules except the perception module; the perception module being deployed on a first operating system in the vehicle controller; and the other modules being deployed on a second operating system in the vehicle controller; the method includes: processing an image collected by an image collector through the perception module to obtain perception result data; and controlling a vehicle based on the perception result data obtained from the perception module by the other modules.

A display device for a vehicle includes: a plurality of imaging units configured to capture images around the vehicle; an image compositing unit configured to composite the images captured by the imaging units to generate a composite image; an image display unit configured to display the composite image generated by the image compositing unit; and an acquiring unit configured to acquire information about an object around the vehicle. The imaging units are arranged such that imaging areas thereof overlap with each other. The image compositing unit is configured to set a boundary between the captured images in the composite image such that the boundary is provided in a part where the imaging areas of the imaging units overlap with each other. In a case where the acquiring unit acquires the information about the object, the image compositing unit changes the boundary.