A method for calibrating a vehicular vision system includes disposing a camera at a vehicle, disposing a processor at the vehicle, and disposing a video display screen in the vehicle so as to be viewable by the vehicle driver. The video display screen is operable to display video images derived from image data captured by the imager of the camera. Image data is captured by the imager of the camera and provided to the processor. The video display screen displays video images derived from image data captured by the imager of the camera. The processor generates a graphic overlay for display with the video images at the video display screen. Responsive to processing captured image data, the vehicular vision system is calibrated by adapting an orientation and position of the image data relative to the generated graphic overlay to a corrected orientation and position relative to the generated graphic overlay.

A display control apparatus includes a captured data acquisition unit, a motion state detection unit, an extracted image data generation unit, a display image data generation unit, and an output unit. The captured data acquisition unit is configured to acquire captured data generated as a result of a camera capturing scenery outside a vehicle. The motion state detection unit is configured to detect a motion state of the vehicle. The extracted image data generation unit is configured to generate an extracted image from the captured data by using an angle of view set in accordance with the motion state. The display image data generation unit is configured to generate display image data related to a display image having a preset image size, from extracted image data. The output unit is configured to output the display image to a display unit having the image size.

A rearward camera of a vehicle electronic mirror system images a rearward view of a vehicle, and a lateral rearward camera unit images each of right and left lateral rearward views of the vehicle. A control device compresses at least one of a rearward view picture after imaging by the rearward camera and right and left lateral rearward view pictures after imaging by the lateral rearward camera unit, at least in a vehicle-width direction, and performs display on an inner mirror display. The control device changes the compression ratio of the picture in the control device, depending on at least one of a state and peripheral situation of the vehicle. Accordingly, when a vehicle rearward side including lateral rearward sides contains a site requiring an easy distance-sense grasp, it is possible to easily grasp distance sense by decreasing the compression ratio of the picture corresponding to the site.

A work vehicle display system utilized in piloting a work vehicle includes a display device having a display screen, a context camera mounted to the work vehicle and positioned to capture a context camera feed of the work vehicle's exterior environment, and a controller architecture. The controller architecture is configured to: (i) receive the context camera feed from the context camera; (ii) generate a visually-manipulated context view utilizing the context camera feed; and (iii) output the visually-manipulated context view to the display device for presentation on the display screen. In the process of generating the visually-manipulated context view, the controller architecture applies a dynamic distortion-perspective (D/P) modification effect to the context camera feed, while gradually adjusting a parameter of the dynamic D/P modification effect in response to changes in operator viewing preferences or in response to changes in a current operating condition of the work vehicle.

A vehicle and a method for controlling the vehicle are provided. The vehicle includes a first camera configured to capture a front image of the vehicle; a head-up display configured to project an image onto a windshield of the vehicle; an input device configured to input a boundary line for setting an area in which the image is projected from the windshield; and a controller configured to determine a projection area in which the image is projected based on the inputted boundary line, to determine an interest area of the front image based on the determined projection area and a speed of the vehicle, and to display the determined interest area in the determined projection area on the head-up display.

Provided is a display control apparatus including a vehicle detector and a processor, in which the processor performs projection conversion for projecting the plurality of captured images onto a projection plane, performs a visual point conversion process for converting at least one of the plurality of captured images into an image viewed from a virtual visual point, and sets a ground height of the virtual visual point when the surrounding vehicle is not detected in a predetermined region to be lower than a ground height of the virtual visual point when the surrounding vehicle is detected in the predetermined region.

An imaging apparatus provided in a moving object to capture an image of an area behind the moving object includes an imaging circuit and an optical system. The imaging circuit outputs an image based on an optical image input to a light-receiving surface. The optical system inputs the optical image to the imaging circuit. The optical system forms a first region at a first magnification and a second region at a second magnification lower than the first magnification. The second region is formed around the first region. The imaging apparatus is installed in the moving object so that, on the light-receiving surface of the imaging circuit, an axis passing through a center of the first region and extending in a direction from which the optical system receives light is inclined toward an upper side of the moving object with respect to a backward direction of the moving object.

This camera monitoring system (20) is intended for providing to a user a view of a scene captured by a camera. To that end, the camera monitoring system (20) comprises a wide angle camera (22A, 22B) for capturing a wide angle image of a scene, a determination unit (28) for determining an area of interest in the scene, an image treatment system (24A, 24B) for providing an undistorted portion, including the area of interest, of the wide angle image, and a display (26A, 26B) for displaying a continuous displayed image of the wide angle image. The displayed image comprises the undistorted portion adjoining at least one distorted portion of the wide angle image.

Vehicle display device (10) including a display unit (50), installed in a cabin of a vehicle and having a display face oriented in a different direction from a direction of a driver (DR), configured to display an image depicting a surrounding area of the vehicle, and a mirror unit (55) installed in the cabin of the vehicle and configured to reflect some or all of an image area displayed on the display unit (50). A visible range of the surrounding area visible to the driver through an image of the display unit (50) reflected in the mirror unit (55) changes according to movement of a viewing position of the driver (DR) with respect to the mirror unit (55).

A partial image generating device has a processor configured to generate a partial image from an image in which the environment surrounding a vehicle has been photographed using an imaging device provided in the vehicle, and to assess whether or not the road represented in the image is straight. The processor is configured so that, when it has been assessed that the road represented in the image is straight, it generates a partial image by cutting out a first region in the image that is estimated to contain the road, based on the vanishing point of the road, and when it has assessed that the road represented in the image is not straight, it generates a partial image by cutting out a second region in the image determined based on the type of the vehicle.