A head-up display (HUD) including a direction-information generator, a shift device, and a display system. The direction-information generator generates direction information to be superimposed on a road surface ahead of a vehicle on which the HUD is mounted. The direction information represents a direction of travel to be followed by the vehicle. The shift device shifts at least some of the direction-change information into the display area when the direction information includes direction-change information to represent a change in the direction of travel and the direction-change information falls outside a display area. The display system displays the direction information within the display area as a virtual image.

A display control device includes: an image acquisition unit configured to acquire captured image data from an imaging unit that captures an image of a peripheral area of a vehicle; a display control unit configured to cause image data based on the captured image data to be displayed on a screen; and an operation receiving unit configured to receive designation of an arbitrary point on the screen, in which the display control unit enlarges display on the screen about the designated point as a center of enlargement in a state where a display position of the designated point does not move on the screen when the operation receiving unit receives the designation of the arbitrary point on the screen.

The present application relates to a method and apparatus for determining a preferred off-road vehicle path including a lidar operative to generate a depth map of an off road surface, a camera for capturing an image of the off road surface, a processor operative to receive the depth map, determine a vehicle path in response to the depth map and a host vehicle characteristic, combine a graphical representation of the vehicle path with the image to generate an augmented image, and a display to display the augmented image to a host vehicle operator.

A method for operating a vehicle camera system including receiving a first image from at least one video camera, identifying a first object in the first image, determining a distance between a vehicle component and the identified object, modifying the first image by incorporating a human machine interface (HMI) within the first image, wherein the human machine interface includes a display configured to communicate the distance between the object and the vehicle component, and displaying the modified image to a vehicle operator.

An image display control device according to an embodiment includes an image generator configured to generate a display image to be displayed on a display device, the display image containing a vehicle exterior image based on at least a part of a captured image by an imager an imaging area of which is from a direction in which a rear end of a vehicle body can be captured to a direction upward from a horizontal direction and a rearward of a vehicle; an area changer configured to change an area of the captured image to be contained in the display image for forward travel and backward travel of the vehicle; and a display controller configured to control the display device to display the display image.

A plurality of images captured by a plurality of cameras respectively to create a plurality of upper viewpoint images. Display images are extracted from the upper viewpoint images, and the extracted display images are synthesized to create an overhead image or bird's eye view image of surroundings, which has an image corresponding to an operating machine at a center of the bird's eye view image. When extracting each of the display images, a region of the display image extracted from the upper viewpoint image is expanded beyond the size of a standard extraction region on the basis of the set height of a mating face. Each of the extracted display images is adjusted to the size of the standard extraction region, and synthesized. Thus, any three-dimensional object (obstacle) present near the boundary between display images constituting the bird's eye view image is displayed.

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).

A rear vision system for a host vehicle and a method of using the same, where the rear vision system includes an electronic display mirror that is designed to replace a traditional rearview mirror. The electronic display mirror has an integrated electronic video display that is coupled to a rearward facing camera at the back of the vehicle and displays a video feed from the camera to the driver in real time. The electronic display mirror can display enhanced video output that shows the area behind the host vehicle, along with performance metrics that are superimposed on the video and provide relevant information to the driver. For example, the enhanced video output may include an estimated time difference between the host vehicle and the closest trailing vehicle superimposed on the video; this may be particularly useful when the host vehicle is involved in a performance driving event, like a race.

A method for dynamically registering a graphic upon a cropped image obtained from a camera device includes capturing an original image obtained from the camera device. Intrinsic calibration information for the camera device, extrinsic information for the camera device and vehicle information are monitored. The cropped image is generated based on cropping parameters to exclude undesirable content from the original image. The intrinsic calibration information is adjusted based on a relationship to the cropping parameters. The graphic is dynamically registered upon the cropped image based on the adjusted intrinsic calibration information for the camera device, the monitored extrinsic information for the camera device and the monitored vehicle information.

A parking assist apparatus of an embodiment includes an area detection unit, a line detection unit, and a target position calculation unit. The area detection unit detects a parking allowable area where the parking of a vehicle is allowable. The line detection unit detects a parking section line provided on a track surface. The target position calculation unit calculates a target parking position by using a detection result of the parking allowable area by the area detection unit when the parking allowable area is detected by the area detection unit, the parking section line is detected by the line detection unit, and the parking section line is located outside the parking allowable area.