An apparatus comprising a sensor, an interface and a processor. The sensor may be configured to generate a video signal based on a targeted view from a vehicle of a perspective of a driver. The interface may be configured to receive status information about one or more components of the vehicle. The processor may be configured to generate a control signal in response to (i) a classification of objects in the video signal and (ii) the status information. The control signal may be used to adjust one or more headlights of the vehicle. The adjustment of the headlights may be based on a location of the objects in the video signal.

A vehicle behavior detection device mounted on an own vehicle detects own vehicle's behavior, in particular driver's right or left turn behavior at an intersection on a roadway. The vehicle behavior detection device is a microcomputer system having a CPU capable of providing an intended direction acquiring section, a turn direction acquiring section, a coincidence judgment section and an information output section. The intended direction acquiring section obtains an intended direction toward which the own vehicle is turning. The turn direction acquiring section acquires a direction to which the own vehicle turns. The coincidence judgment section detects whether or not the intended direction coincides with the turn direction of the own vehicle. The information output section provides warning regarding wide right or left turn of the own vehicle when the judgment result indicates that the intended direction does not coincide with the turn direction of the own vehicle.

Information related to a vehicle can be displayed by projecting an image based on the information on a road surface or the like. An image projection apparatus that projects an image includes: a sensor unit that acquires information related to a vehicle; and an image projection unit that projects the image based on the information acquired by the sensor unit.

A vehicle light fixture include a first light distribution illuminator that emits a first light distribution to the front of a vehicle, and a second light distribution illuminator that emits a second light distribution having a light-dark boundary line at least on a side of the vehicle, wherein illumination of the first light distribution illuminator and the second light distribution illuminator is controlled in response to a predetermined operation of the first light distribution illuminator by the driver of the vehicle. The second light distribution illuminator includes a light source, and a projection lens that projects light emitted from the light source to form an illumination pattern surrounded by multiple light-dark boundary lines and emit the illumination pattern to a side of the vehicle, and the projection lens focuses more of the light emitted from the light source passing outwardly from the optical axis of the projection lens.

A vehicle lamp includes a light source that shines a laser beam and a laser scanning unit that has a single or plurality of acousto-optic devices, and the laser scanning unit can control an angle at which a laser beam that is incident on the acousto-optic devices is deflected. The vehicle lamp is strong enough to deal with vibrations and withstands the application to a motor vehicle.

A lamp control system, a lamp control method, and a vehicle are disclosed. The lamp control system includes a lamp configured to form a light distribution (LV) in a front area including a driving lane; a sensing module configured to detect a change in the driving lane of a vehicle; and a processor configured to control the lamp so that a brightness distribution, a formation position, or a shape of the front area where the light distribution (LV) is formed is variable based on information about a driving lane change and information about a driver's driving tendency.

A lamp control system, a lamp control method, and a vehicle are disclosed. The lamp control system includes a lamp configured to form a light distribution (LV) in a front area including a driving lane; a sensing module configured to detect a change in the driving lane of a vehicle; and a processor configured to control the lamp so that a brightness distribution, a formation position, or a shape of the front area where the light distribution (LV) is formed is variable based on information about a driving lane change and information about a driver's driving tendency.

A lamp control system for a moving object, and a lamp control method therefor are provided. The lamp control system includes a lamp to emit a beam pattern, among a plurality of beam patterns, toward a front of the moving object, a memory for storing location-based driving data or data obtained by analyzing and refining the location-based driving data, and a processor to control the beam pattern based on the data stored in the memory and location information of the moving object.