A vehicular monitoring system includes a camera disposed at a vehicle and viewing interior of the vehicle. The camera is operable to capture image data. Image data captured by the camera is provided to a data processor and is processed at the data processor. A wireless communication link links the vehicle with a remote communication device located remote from the vehicle. The remote communication device, responsive to communication received from the vehicle via the wireless communication link, displays video images derived from image data captured by the camera.

A method for representing the surroundings of a vehicle. The method includes: detecting the surroundings of the vehicle and ascertaining obstacles in the surroundings with the aid of surroundings sensors of the vehicle; displaying a first depiction encompassing a representation of the surroundings including the obstacles and a representation of the vehicle on a display device; establishing an approach by the vehicle to an ascertained obstacle due to the fact that a predefined distance to the obstacle has been undershot; and displaying a second depiction including a detail, enlarged in comparison to the first depiction, of the representation of the surroundings including the obstacles and the representation of the vehicle on the display device, the detail representing the area of the surroundings and of the vehicle at which the approach by the vehicle to the obstacle was established.

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 driving assistance apparatus is provided in which the detection range of a left-front-corner sonar (12a) located at the vehicle's left front corner is included in the field of view of a second imaging means (14) located at the vehicle's left front corner. When the left-front-corner sonar (12a) detects a three-dimensional object at the vehicle's left front corner, an image processing means (3) synthesizes an image of the image created using a second imaging means (14) and the images created with four cameras (7a-7d) for imaging the complete periphery of the vehicle, and creates a bird's-eye-view image (40b). The detection range of the left-front-corner sonar (12a) is included within a region of the bird's-eye image (40b) on the basis of the image created with the second imaging means (14).

A movable carrier auxiliary system includes a sign detecting device including an image capturing module, a storage module, and an operation module. The image capturing module has at least two lenses having refractive power for capturing an environment image around a movable carrier. The storage module stores a plurality of sign models. The operation module is electrically connected to the image capturing module and the storage module. A processing method of the movable carrier auxiliary system includes steps of: detect whether the environment image has a sign image that matches at least one of the image models or not, and correspondingly generate a detection signal via the operation module, thereby to identify signs around the movable carrier.

Proposed are a device provided in a vehicle and a method for controlling same. A device provided in a vehicle according to one embodiment of the present disclosure comprises: a first module which executes a first application and outputs first video data corresponding to the first application; and a second module which is wired or wirelessly connected to the first module and outputs video data, which is the same as the first video data, at a first timing. The second module is designed to output second video data which is different from the first video data in response to, for example, an event which has occurred at a second timing after the first timing.

A driver's cab is located at the front end portion of a vehicle. A sensor unit is provided on the front face of a body of the vehicle and is located at the same height as the driver's-cab floor of the driver's cab. A floor crossing member extends along the lateral direction of the vehicle on the driver's-cab floor between the sensor unit and an accelerator pedal. The floor crossing member has both sides coupled one-to-one with a left front side member and a right front side member extending along the longitudinal direction of the vehicle, respectively, at the left front portion and right front portion of the vehicle. After entering the driver's cab due to a frontal collision, the sensor unit abuts on the floor crossing member, leading to suppression of the distance of entry of the sensor unit into the driver's cab.

A method for operating a camera-monitor system for a motor vehicle, in which the camera-monitor system has a camera that is designed to provide an image of an environment of the motor vehicle and has a monitor for representing images from the camera comprises providing an image from the camera, ascertaining an attention-relevant object in the environment, temporarily changing at least one representation property of the image in dependence on the ascertained object to form a changed image, and representing the changed image on the monitor.

A vehicular control system includes a first communication device disposed at a first vehicle, a second communication device disposed at a second vehicle, a camera disposed at the second vehicle, and an electronic control unit (ECU) of the second vehicle. The vehicular control system determines a potential collision between the first vehicle and the second vehicle based at least in part on (i) a wireless communication received at the second communication device from the first communication device and provided to the ECU of the second vehicle and/or (ii) processing at the ECU of image data captured by the camera disposed at the second vehicle. Responsive to determination of the potential collision between the first vehicle and the second vehicle, the vehicular control system controls (i) braking of the second vehicle and/or (ii) steering of the second vehicle.

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.