An ECU generates an overhead image including a vehicle and a vehicle surrounding area, on the basis of a plurality of images taken by a plurality of cameras mounted on the vehicle. When a distance between an object existing in an overlapping portion of imaging areas of the plurality of cameras and the vehicle is within a threshold and the object exists in a traveling direction of the vehicle, the overlapping portion is divided into two pairs of a road surface image and an object image, and combination is performed by alpha blending with an α value for the object image being set to 1 and an α value for the road surface image being set to 0 for an area that is the object image in one of the two pairs and is the road surface image in the other of the two pairs, to generate the overhead image.

A vehicular control system includes a central control module vehicle, a plurality of vehicular cameras disposed at a vehicle and viewing exterior of the vehicle, and a plurality of radar sensors disposed at the vehicle and sensing exterior of the vehicle. The central control module receives vehicle data relating to operation of the vehicle. The central control module is operable to process (i) vehicle data, (ii) image data and (iii) radar data. The central control module at least in part controls at least one driver assistance system of the vehicle responsive to (i) processing at the central control module of vehicle data, (ii) processing at the central control module of image data captured by at least the forward-viewing vehicular camera and (iii) processing at the central control module of radar data captured by at least a front radar sensor.

A camera system is installed on the front end of a vehicle, either on the left front, the right front, or both sides. The camera is linked via wired or wireless connection to an onboard computer and a navigation display that is located within the passenger compartment of the vehicle. The driver reviews a visual description on the display of any oncoming traffic in the form of motor vehicles, pedestrians, cyclists, animals and the like on the navigation display via a single screen, split screen or alternating screens. The camera system can include a speed sensor that detects when the vehicle reaches a threshold speed to activate or de-activate the camera. Alternatively, the computer can activate the system when a turn signal is activated, and de-activate the system when the turn signal is no longer activated. This camera system can be retrofitted into older vehicles.

The present disclosure relates to an information processing apparatus, an information processing method, and a program that make it possible to reduce an amount of communication data that flows through an in-vehicle network and is necessary for automated driving.

An image sensor captures an image of the surroundings of an own automobile; and a recognition section performs object recognition processing of recognizing an object in the captured image, and outputs, to an automated driving controller, an object recognition processing result obtained by the object recognition processing. Further, speed information and distance information are associated with the object recognition processing result to be output as metadata, the speed information being information regarding a speed of an object in the surroundings of the own automobile and being obtained by a millimeter-wave radar, the distance information being information regarding a distance to the object in the surroundings of the own automobile and being obtained by LiDAR. The present disclosure is applicable to an in-vehicle system.

A method of monitoring a vehicle bottom condition is provided. in which forward, left-side, right-side, and rear images of a vehicle are received from a camera unit of the vehicle, and traveling distance information of the vehicle is received from a sensor unit of the vehicle. The images received from the camera unit based on the traveling distance information received from the sensor unit are stored. A vehicle bottom image is then generated based on the stored image, the generated vehicle bottom image is matched with a surround view monitoring (SVM) image of the vehicle, and the SVM image matched with the vehicle bottom image is output.

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.

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.

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.