An electronic device configured to charge an occupant in a vehicle. The electronic device includes: an interface unit configured to exchange signals with at least one internal camera configured to capture at least one image of an inside of a cabin of the vehicle; at least one processor; and at least one computer memory that is operably connectable to the at least one processor and that has stored thereon instructions which, when executed, cause the at least one processor to perform operations including: receiving, through the interface unit, image data that was generated based on processing the at least one image of the inside of the cabin captured by the at least one internal camera; and generating cost charging data based on a motion of a user detected from the received 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 vehicle display control device comprising memory and a processor coupled to the memory. The processor being configured to perform control to detect a position of a preceding vehicle running in front of the vehicle, based on the position of the preceding vehicle, perceive whether or not an entirety of the preceding vehicle has departed from the display region, and display an acquisition image that is superimposed on or adjacent to the preceding vehicle in the display region in accordance with the position of the preceding vehicle and, when the entirety of the preceding vehicle departing from the display region is perceived, display the acquisition image as a flashing display at an end portion at a side of the display region at which the entirety of the preceding vehicle has departed.

A vehicle can include a window. The window can include an interior side and an exterior side. The vehicle can include a camera operatively positioned to capture visual data of a portion of an exterior 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 cause the dual-sided transparent display to display interior visual information on the interior side. The interior visual information can include the visual data of the portion of the exterior environment of the vehicle.

A detection system for a vehicle comprises a blind spot detection module and a glasses module. The blind spot detection module comprises a first video recording device recording a vehicle surrounding image; a first identification device generating a blind spot identification result; a first determination device determining whether to transmit the vehicle surrounding image and/or a blind spot warning message; and a transmitting device transmitting the vehicle surrounding image and/or the blind spot warning message. The glasses module comprises a receiving device receiving the vehicle surrounding image and/or the blind spot warning message; a second video recording device recording a user surrounding image; a second identification device generating an eye identification result; a second determination device determining whether to transmit the user surrounding image and/or an eye warning message via an artificial intelligence (AI); and a display device displaying the user surrounding image and/or the eye warning message.

A vehicle is configured to image, with an outside camera, an identification mark associated with a content provided by a service provider, output the content associated with the imaged identification mark to an occupant in a cabin of the vehicle, acquire operation information on the occupant relating to the output content, and acquire information regarding the occupant when the occupant performs operation relating to the content in the vehicle cabin. An information processing apparatus is configured to, when determining that the output content is not selected by the occupant based on the operation information on the occupant, determine whether or not to update the content that is not selected, based on the information regarding the occupant.

A power source supply circuit supplies an output power source of a battery to a vehicle control apparatus that includes a first instrument control portion that selectively receives a voltage applied to a first power source input portion or a voltage applied to a second power source input portion as an operation voltage and a second instrument control portion that receives a voltage applied to a second power source input portion or a third power source input portion as the operation voltage.

A video acquisition unit acquires a video from an imaging unit provided in a vehicle to capture a scene around the vehicle. A display unit is provided in the vehicle to display the video captured by the imaging unit. A control unit switches, when it is predicted that a passenger of the vehicle will leave the vehicle, a mode of the display system to a mode in which visibility for the passenger is improved.

The assembly mounted on a moving device includes an element, an optical system configured to form a high resolution image near an optical axis in a first region of a light receiving surface of the element and form a low resolution image of a peripheral portion separated from the optical axis in a second region wider than the first region of the light receiving surface of the element, a generation unit configured to generate a first captured image from pixel data in the first region and generate a second captured image from pixel data in the second region, and a control unit configured to selectively display the first captured image or the second captured image on a display unit in accordance with a moving direction of the moving device.

A method of operating an immersive display includes obtaining first images of environment in a first region in front of the immersive display, obtaining second images of environment in a second region outside the first region, which second region is not in front of the immersive display, displaying the first images of the environment on a first area of at least one display of the immersive display to provide a field of view of the environment in front of the immersive display, and displaying the second images of the environment in the second region on a second area of the at least one display to provide images outside the field of view of the environment in front of the immersive display. The first area is delineated from the second area.