A vehicle periphery display device includes: an acquisition portion acquiring a captured image obtained by imaging a periphery of a vehicle with an imaging portion; and a display processing portion causing a display image that is a stereoscopic image of the vehicle and the periphery of the vehicle to be displayed on a display portion on the basis of the captured image. The display processing portion causes at least one of a contour guide line representing a contour of the vehicle, and a predicted course guide line that is a trajectory drawn by the contour guide line according to movement of the vehicle to be included in the display image, and changes a position of at least one of the contour guide and predicted course guide lines such that the contour guide and predicted course guide lines are present above a road surface when the vehicle is turned.

A system for assisting in aligning a vehicle for hitching with a trailer includes a vehicle steering system, a detection system outputting a signal including object position information of an area to a rear of the vehicle, and a controller. The controller receiving the object position data and identifying a targeted trailer and at least one additional object within the area to the rear of the vehicle and controlling the vehicle steering system to maneuver the vehicle during reversing to align a hitch ball mounted on the vehicle to a coupler of the targeted trailer. Upon aligning the hitch ball with the coupler, the controller presents an indication, if it is determined that the at least one additional object is within a threshold distance of a side of the targeted trailer.

An electronic mirror system presents circumstances surrounding a moving vehicle by displaying an image presenting the circumstances surrounding the moving vehicle. The electronic mirror system includes an image display and an optical system. The image display displays, every time image data is acquired from an image capturing unit, the image, based on the image data acquired from the image capturing unit, on a display screen. The image capturing unit continuously shoots video presenting the circumstances surrounding the moving vehicle. The optical system condenses, into an eye box, a light beam representing the image displayed on the display screen to make a user, who has a viewpoint inside the eye box, view a virtual image based on the image displayed on the display screen. The display screen is arranged to be tilted with respect to an optical path that leads from the display screen to the optical system (30).

A system in a vehicle for generating and displaying three-dimensional images may comprise a first imager having a first field of view; a second imager having a second field of view at least partially overlapping the first field of view, the second imager disposed a distance from first imager; and an image signal processor in communication with the first and second imagers; wherein the image signal processor is configured to generate an image having a three-dimensional appearance from the data from the first and second imagers. The first and second imagers may be disposed on a vehicle. The first and second imagers may be configured to capture a scene; and the scene may be exterior to the vehicle.

A system for assisting in aligning a vehicle for hitching with a trailer includes a vehicle steering system, a detection system outputting a signal including scene data of an area to a rear of the vehicle, and a controller that controls the vehicle steering system to maneuver the vehicle according to an initial alignment maneuver that positions the vehicle relative to the trailer, such that the trailer is within the area to the rear of the vehicle. The controller further receives the scene data and identifies the trailer within the area to the rear of the vehicle, derives a backing path to align a hitch ball mounted on the vehicle to a coupler of the trailer, and controls the vehicle steering system to maneuver the vehicle including reversing along the backing path.

A vehicular camera system includes an attaching structure configured to attach at an in-cabin side of a vehicle windshield. A camera module accommodates a circuit board and an imager and the camera module includes a lens aligned with the imager. The attaching structure includes a camera module receiving portion having an opening at a lower portion of the camera module receiving portion. With the attaching structure attached at the in-cabin side of the vehicle windshield, the camera module is inserted upward through the opening and is at least partially received in the camera module receiving portion to attach the camera module at the camera module receiving portion. With the attaching structure attached at the in-cabin side of the vehicle windshield and with the camera module at least partially received in the camera module receiving portion, the imager views through the vehicle windshield and forward of the vehicle.

An interactive vehicle safety system having capabilities to improve peripheral vision, provide warning, and improve reaction time for operators of vehicles. For example, the interactive vehicle safety system may have capabilities for portraying objects, which are being blocked by any of the structural pillars and/or mirrors of a vehicle (such as a truck, van, train, etc.). The interactive vehicle safety system disclosed may comprise one or more image capturing devices (such as camera, sensor, laser), distance and object sensors (such as ultrasonic sensor, LIDAR radar sensor, photoelectric sensor, and infrared sensor), a real-time image processing of an object, and one or more display systems (such as LCD or LED displays). The interactive vehicle safety system may give a seamless 360-degree front panoramic view to a driver.

A display controller includes: an image generator configured to generate a three-dimensional image of surroundings of a vehicle and output a display image; an instruction determiner configured to determine an instruction of a user in accordance with a position operated by the user; and a viewpoint changer configured to change a viewpoint parameter related to generation of the three-dimensional image on a basis of the instruction of the user, wherein the instruction determiner sets a plurality of regions corresponding to different viewpoint parameters in the display image, the instruction determiner determines the instruction of the user on a basis of a region where the position operated by the user, the viewpoint changer changes the viewpoint parameter in accordance with the instruction of the user, and the instruction determiner sets the plurality of regions in the three-dimensional image after a change.

A display controller includes: an image generator configured to generate a three-dimensional image of surroundings of a vehicle and output a display image; an instruction determiner configured to determine an instruction of a user in accordance with a position operated by the user; and a viewpoint changer configured to change a viewpoint parameter related to generation of the three-dimensional image on a basis of the instruction of the user, wherein the instruction determiner sets a plurality of regions corresponding to different viewpoint parameters in the display image, the instruction determiner determines the instruction of the user on a basis of a region where the position operated by the user, the viewpoint changer changes the viewpoint parameter in accordance with the instruction of the user, and the instruction determiner sets the plurality of regions in the three-dimensional image after a change.

An electronic mirror system presents circumstances surrounding a moving vehicle by displaying an image presenting the circumstances surrounding the moving vehicle. The electronic mirror system includes an image display and an optical system. The image display displays, every time image data is acquired from an image capturing unit, the image, based on the image data acquired from the image capturing unit, on a display screen. The image capturing unit continuously shoots video presenting the circumstances surrounding the moving vehicle. The optical system condenses, into an eye box, a light beam representing the image displayed on the display screen to make a user, who has a viewpoint inside the eye box, view a virtual image based on the image displayed on the display screen. The display screen is arranged to be tilted with respect to an optical path that leads from the display screen to the optical system (30).