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.

The present invention is directed to a surround view system and method thereof. The surround view system comprises a surround image sensing module which obtains images of surrounding view and output image data, a vehicle status retrieval module which retrieves vehicle status information, a processing module which generates adaptive surround view based on the image data and the vehicle status information; and an outputting module which outputs the adaptive surround view.

The surrounding vehicle display system comprises an object detection device detecting an object in surroundings of a vehicle, an electronic control unit, and a display device. The electronic control unit is configured to generate an object mark based on an output of the object detection device and identify the object mark. The display device displays the surrounding vehicle as a vehicle icon when the object mark is identified as a surrounding vehicle by the electronic control unit. The electronic control unit is configured to determine a position of the vehicle icon with respect to the vehicle on the display device and offset a center position of the vehicle icon from a center position of the object mark identified as the surrounding vehicle based on a predetermined size of the vehicle icon.

An apparatus includes an interface and a processor. The interface may be configured to receive pixel data corresponding to an exterior view from a vehicle. The processor may be configured to (a) process the pixel data arranged as video frames, (b) generate video data for a display in response to the video frames, (c) store a plurality of view preferences for the display, (d) determine (i) a current location of the vehicle, (ii) a current status of the vehicle, (iii) a current maneuver being performed, and (iv) which portion of the current maneuver is being performed, and (e) generate an output signal to select a view for the display. Each view preference generally corresponds to one or more of (i) a location, (ii) a vehicle status, (iii) a maneuver, and (iv) a portion of the maneuver, when the maneuver comprises more than one portion. The processor may switch between a plurality of view preferences associated with the maneuver based on a plurality of precise locations corresponding to a plurality of portions of the maneuver. The processor may determine a current precise location within the maneuver by calculating distances using image-based localization applied to the video frames. The output signal may be generated in response to the current precise location within the maneuver and the current status matching the precise location and the vehicle status, respectively, of a particular one of the plurality of view preferences corresponding to the plurality of portions of the maneuver. The view selected may be determined based on the particular one of the plurality of view preferences.

A left infrared camera module provided in a vehicle includes: a left infrared emitting unit configured to emit infrared rays toward an outside, and a left infrared camera configured to acquire infrared image data indicating a surrounding environment of the vehicle. The left infrared emitting unit and the left infrared camera are mounted on a left C-pillar of the vehicle.

The disclosure includes a technology feature that uses an overhead view camera system to view and record any activity 360 degrees around the vehicle. The system includes four exterior cameras, an interior camera, a data collector, a wireless key remote, and a remote activation/viewing platform. Exterior cameras together have a 360 degree range around the vehicle.

An overhead-view image generation device includes: a moving amount calculation unit that calculates a moving distance of a vehicle; a linear overhead-view image generation unit that generates an overhead-view image obtained by conversion of a viewpoint of a captured image of a camera into an overhead viewpoint, and generates a linear overhead-view image obtained by conversion of a shape of the generated overhead-view image into a linear shape; a distance-based turning angle generation unit that calculates, using a turning amount of the vehicle indicated by sensor data of a steering angle sensor and the moving distance calculated by the moving amount calculation unit, distance-based turning angle information indicating a turning angle of the vehicle based on the moving distance; and an overhead-view image reconstruction unit that reconstructs the overhead-view image using the linear overhead-view image and the distance-based turning angle information.

An electronic mirror apparatus includes: a camera provided on a lateral surface of a vehicle, the camera being configured to pick up an image of a predetermined pickup range in a vehicle lateral direction and in a vehicle rearward direction; a display device disposed at such a position that a driver visually recognizes the display device; and an electronic control unit configured to perform a process for displaying the image picked up by the camera, on the display device, the electronic control unit being configured to display, on the image, an assist image expressing at least one of an outer part of a region where the vehicle occupies a road surface in planar view of the vehicle and an outside position a predetermined distance away from the outer part of the region where the vehicle occupies the road surface in planar view of the vehicle.

An apparatus includes a plurality of capture devices and a processor. The plurality of capture devices may each be configured to generate video frames corresponding to an area outside of a vehicle. The processor may be configured to receive the video frames from each of the plurality of capture devices, generate video data for a display in response to the video frames, store a view preference for the display corresponding to (i) a location and (ii) a vehicle status, determine a current location and a current status of the vehicle and generate an output signal to select a view for the display. The output signal may be generated in response to the current location matching the location and the current status matching the vehicle status. The view selected may be determined based on the view preference.

Charging equipment of a vehicle charging system comprises an information indicator configured to indicate authentication information, and an authentication device configured to perform authentication using the authentication information. A vehicle of the vehicle charging system comprises an imaging device, and a communication device configured to send the authentication information acquired by the imaging device to the authentication device. The authentication device of the charging equipment is configured to perform the authentication using the authentication information received from the communication device, and is configured to, if the authentication has succeeded, permit the vehicle to use a wireless LAN.