A vehicle light assembly, a heater plate, and a method for vehicle light heating. The vehicle light assembly includes an outer lens and a heater plate. The heater plate is moveable between a stowed position and a deployed position, the heater plate being situated in operative relationship with the outer lens and the heater plate being energized when in the deployed position.

Disclosed is a case structure for a rear combination lamp in an automobile in which a rear combination lamp case in a corner portion formed in a rear portion of a vehicle is formed in a corner case having a substantial triangle pyramid shape by a rear plate, a side plate and a planner plate, wherein the rear plate forms a case rear face on which a concave notch portion is formed in a substantial center, wherein the side plate forms an air communication side face which is formed so as to gradually become narrower width toward a rear thereof, and wherein the planner plate forms a concave air communication path in a center thereof so that a terminal end of the concave air communication path communicates with the concave notch portion of the rear plate.

The invention relates to a method for producing a roof rack, to an extruded profile for use in a method of this nature and to a novel roof rack for a vehicle. The novel roof rack for vehicles consists of an extruded profile (1) of aluminum, wherein the rail (13) is formed by a tubular profile part of the extruded profile (1), and the end feet (11, 12) are formed from a bend section of the tubular profile part. The roof rack has different cross-sections in the longitudinal direction, which are created by machining of at least one additional profile web on the extruded profile (1). Freely selectable lateral contours (20, 20) for a roof rack can be achieved in this way.

A vehicle includes a battery charger and an exterior lamp assembly. The assembly includes a housing defining a cavity, and an electrical port including at least one electrical terminal disposed within the cavity, electrically connected with the battery charger, and configured to be electrically connected with an electrical power grid remote from the vehicle.

Techniques for drone device control are provided. In one example, the technique includes monitoring, by a drone device operatively coupled to a processor and allocated to a vehicle in operation, one or more conditions associated with the vehicle. The technique also includes, in response to identifying, by the drone device, a defined condition of the one or more conditions: moving, by the drone device, to a position relative to the vehicle and determined based on the defined condition; and performing, by the drone device, an indication operation determined based on the defined condition.

A backup camera system integrates various capabilities in a common housing to deliver enhanced safety and convenience functions for less cost and improved utility. Apparatus such as an inertial measurement unit (IMU) may be used to automatically detect when the vehicle is moving in reverse, such that no signal is required from the vehicle to determine that the vehicle is moving in reverse. The IMU may further detect a crash situation. A sound or light generator may provide an alert to an area surrounding the vehicle. Integrated communications capabilities provide for remote control of various functions and the exchange of signals and information to remote devices facilitating vehicle-to-vehicle, vehicle-to-infrastructure or infrastructure-to-vehicle communications. The system may further integrate proximity detection, imaging and computer-readable code interpretation, and GPS location.

The invention relates to a vehicle lighting system based on infrared light sources, the vehicle lighting system comprising: an infrared matrix lamp, which comprises a plurality of infrared light sources arranged in a matrix and which is configured to be mounted on a vehicle to provide an illumination range with respect to the vehicle, wherein each of the plurality of infrared light sources corresponds to an illumination region in the illumination range; and a matrix lamp controller configured to turn on, when a target region needs to be illuminated, an infrared light source in the infrared matrix lamp corresponding to the target region on the basis of relative position information between the target region and the vehicle, wherein the relative position information comprises an angular position of the target region relative to a vehicle reference. The invention further relates to a vehicle comprising the vehicle lighting system.

Examples of the present disclosure relate to techniques for headlamp heater control. In examples, a headlight assembly comprises a heater, which is used to prevent or remove condensation/precipitation on a lens of the headlamp assembly. Given it may be difficult for an individual to know when to manually turn the headlamp heater on, an electronic control unit (ECU) may evaluate a set of rules to determine when to automatically enable or disable the headlamp heater. The rules may be associated with atmospheric conditions outside the vehicle, the state of the vehicle (e.g., whether windshield wipers are turned on, whether windshield defog is enabled, whether a mirror heater is turned on, etc.), and/or user input received by an ECU of the vehicle, among other examples.

There is provided a mobile object including an imaging unit configured to capture a perimeter of the mobile object, a speaker configured to be capable of controlling directivity, a determination unit configured to determine whether the mobile object is in a driving mode, and a speaker control unit configured to control the speaker in the driving mode in a manner that predetermined audio is output toward a warning target that is recognized based on a captured image captured by the imaging unit, and to control the speaker in a non-driving mode in a manner that the predetermined audio is output in a non-directional way.

An illuminated trim fitting for a motor vehicle, in particular a trim fitting as a cover fitting of a sealing strip for the window channel of a vehicle door, is intended to provide a high-quality illuminating effect accompanied at the same time by a simple structural design, low manufacturing costs and space-saving attachment. In addition, the trim fitting is to differ as little as possible externally from non-illuminated trim fittings. For this purpose there is provision that a light gap is formed between a profiled strip of the trim fitting and the adjacent vehicle outer skin, through which light gap the light emitted by a lighting structure provided on the rear of the trim fitting can exit to the outside.