A system for navigating a vehicle automatically from a current location to a destination location without a human operator is provided. The system of the vehicle includes a global positioning system (GPS) for identifying a vehicle location and a communications system for communicating with a server of a cloud system. The server is configured to identify that the vehicle location is near or at a parking location. The communications system is configured to receive mapping data for the parking location from the server, and the mapping data is at least in part used to find a path at the parking location to avoid a collision of the vehicle with at least one physical object when the vehicle is automatically moved at the parking location. The mapping data is processed by electronics of the vehicle so that when the vehicle is automatically moved collision with the at least one physical object is avoided and the electronics of the vehicle is configured to process a combination of sensor data obtained by sensors of the vehicle. The processing of the sensor data uses image data obtained from one or more cameras and light data obtained from one or more optical sensors.

A vehicle control system including: a vehicle configured to be movable along a predetermined route, the vehicle including at least an image capturing apparatus; a display apparatus configured to display a video image captured by the image capturing apparatus, the display apparatus being installed in a remote place that is remote from the vehicle; a first operation terminal installed in the remote place; a control apparatus configured to control movement of the vehicle based on first operation information input through the first operation terminal; and a second operation terminal installed in a place that is closer to the vehicle than to the remote place, in which the control apparatus is configured to assist, based on second operation information input through the second operation terminal, the control of the movement of the vehicle that is based on the first operation information.

The present technology relates to an information processing device, an information processing method, and an information processing system by which a user can easily recognize a position of a sensor having a defect from among sensors mounted on a vehicle. Position-related information about a relative position or direction with respect to a vehicle is acquired, and a combined image obtained by combining a defect image representing a position of the sensor having a defect from among the sensors mounted on the vehicle with a vehicle image reflecting the vehicle is displayed in response to the position-related information. The present technology can be applied so that a user can recognize a sensor having a defect from among the sensors mounted on a vehicle.

An information communications system for a construction machine includes a hardware processor. The hardware process is configured to receive construction information from a contractor-side device and receive weather information from a weather server. The hardware processor is configured to generate advisory information based on the received construction information and the received weather information.

Methods and systems for sharing image data between vehicles. The system includes an image sensor of a first vehicle configured to detect image data of an environment around the first vehicle as it traverses a road. The system also includes a transceiver of the first vehicle configured to communicate the detected image data. The system also includes a transceiver of a second vehicle configured to receive the detected image data. The system also includes a display screen of the second vehicle configured to display a view of the environment around the road based on the detected image data.

A system and method for assisting drivers of vehicles are described. The systems and methods provide an extended view of the area surrounding the driver's vehicle while providing real-time object trajectory for objects and other vehicles that may enter the driver's reactionary zone. The system and methods capture images of the area surrounding the driver's vehicle and create a composite image of that area in real-time and using Augmented Reality (AR) create a 3-D overlay to warn the driver as objects or other vehicles enter the driver's reactionary zone so that a driver can make more informed driving decisions.

A vehicular camera includes a lens holder, a first printed circuit board and a second printed circuit board. The first and second printed circuit boards are stacked and overlap one another. Circuitry disposed at the first printed circuit board is electrically connected with circuitry disposed at the second printed circuit board via board-to-board electrical connection. The circuitry disposed at the first printed circuit board includes an imaging sensor at a first side of the first printed circuit board. Thermally conductive material is disposed between the second printed circuit board and a second side of the first printed circuit board. The thermally conductive material is in thermally-conductive contact with the first and second printed circuit boards. The vehicular camera includes a rear housing, which includes an electrical connector portion. The electrical connector portion of the rear housing may include an electrical plug connector.

A working vehicle is capable of autonomously traveling on a target traveling route and appropriately performing illumination during autonomous traveling to enable an operator to reliably confirm the presence of obstacles or the like on the target traveling route. The working vehicle includes a traveling body to autonomously travel on the target traveling route, illumination lamps located on the traveling body to respectively illuminate different directions, and a controller to change a control relating to a way of turning on the illumination lamps during the autonomously traveling.

A system and method for assisting drivers of vehicles are described. The systems and methods provide an extended view of the area surrounding the driver's vehicle while providing real-time object trajectory for objects and other vehicles that may enter the driver's reactionary zone. The system and methods capture images of the area surrounding the driver's vehicle and create a composite image of that area in real-time and using Augmented Reality (AR) create a 3-D overlay to warn the driver as objects or other vehicles enter the driver's reactionary zone so that a driver can make more informed driving decisions.

A vehicle can include a window including an interior side and an exterior side. The vehicle can include a camera located on an exterior of the vehicle. The camera can be operatively positioned to capture visual data of a blind spot of an external environment of the vehicle. The vehicle can include a dual-sided transparent display forming at least a portion of the window. The vehicle can include a processor operatively connected to the camera and the dual-sided transparent display. The processor can be configured to selectively cause the dual-sided transparent display to display exterior visual information on the exterior side. The processor can be configured to selectively cause the dual-sided transparent to display interior visual information on the interior side. The interior visual information can include the visual data of the blind spot of the vehicle.