A bending light device for a vehicle diffracting light emitted from a light source and deflecting the light at a desired angle and in a desired direction may include an ultrasonic light deflector configured to diffract light incident thereon in a selected direction by emitting an ultrasonic beam to the incident light, a light reflection unit configured to reflect light emitted from a light source to the ultrasonic light deflector, a projection lens configured to project light incident thereon after passing through the ultrasonic light deflector to radiate the light outside, and a converging lens arranged between the ultrasonic light deflector and the projection lens and configured to converge the light having passed through the ultrasonic light deflector on the projection lens.

The invention is related to a method for controlling a light pattern provided by an automotive lighting device of an automotive vehicle, wherein a dynamic portion of the light pattern is provided at least by a matrix arrangement of light sources. This method includes the steps of sensing a turn in a steering system of the automotive vehicle, dividing the dynamic portion in a first portion and a second portion, shifting the operation of the light sources associated to the first portion in the same direction as the sensed turn and create a third portion between the shifted first portion and the second portion. The invention also provides an automotive lighting device with control means to perform the steps of the method.

A headlight controller and a vehicle headlight system including an ADB and AFS can include a headlight controller and an optical unit. The headlight controller can include a system controller and a camera photographing vehicles located in a travelling direction of a subject vehicle, and the system controller can be configured to output a control signal to provide favorable light distribution patterns by using image data output from the camera in accordance with traffic conditions. The optical unit can be configured to emit beam lights using lights emitted from a first and second light-emitting device via a projector lens so that the beam lights can be used as a high/low beam without movable parts. Thus, the disclosed subject matter can include providing vehicle headlight systems that can form various favorable light distribution patterns by utilizing the characteristics of the controller and the optical unit in accordance with the traffic conditions.

A light-emitting diode apparatus includes a support substrate; and a light-emitting diode array formed of multiple light-emitting diodes arranged two-dimensionally on the support substrate, constituting a light distribution center having a highest brightness in the light-emitting diode array, wherein the multiple light-emitting diodes are divided into a plurality of control units, drive currents of which can be individually controlled, wherein the plurality of control units include a plurality of composite control units in each of which a plurality of light-emitting diodes are connected in series, and wherein among the plurality of light-emitting diodes in each of the composite control units, a light-emitting diode which is positioned farther from the light distribution center has a larger light-emitting area than that of a light-emitting diode which is positioned nearer from the light distribution center.

An apparatus for controlling a vehicle light with adjustable light output is provided, whereby the apparatus includes a processor configured to receive on-board diagnostics (OBD) data and to determine a light output mode for the vehicle light in accordance with the OBD data, whereby the OBD data indicates a vehicle condition. The apparatus includes a transceiver coupled to the processor that is configured to signal the light output mode to the vehicle light. A method of controlling a vehicle light is provided that includes receiving OBD data from an OBD system in a vehicle, whereby the OBD data determines a vehicle condition, determining a light output mode of the vehicle light in accordance with the OBD data, and sending to the vehicle light appropriate commands for adjusting the light output in accordance with the determined light output mode.

Each of a pair of (left and right) lamp modules is equipped with a first lamp unit having four first light sources and a second lamp unit having a single second light source, and a horizontally long first light distribution pattern or part of it is formed by selectively lighting one or more of the four first light sources. Furthermore, a second light distribution pattern that is smaller and brighter than the first light distribution pattern is formed by lighting the second light source. The first light distribution pattern and the second light distribution pattern are combined, whereby a high-luminous-intensity region is formed as an overlap of them. The first lamp unit and the second lamp unit are configured so as to be able to swing in a horizontal plane so that the high-luminous-intensity region can be shifted in the left-right direction according to a vehicle running situation.

A vehicular lighting apparatus is relatively small, low cost, superior in mountability, and offers a superior design. The vehicular lighting apparatus attachable to a front end of a vehicle includes: a composite lens element that is a light guide element constructed by molding a translucent resin substantially into a plate-like shape; a planar light-emitting unit that emits illumination light; an optical system that transforms planar light from the light-emitting unit into linear light and that causes the linear transformed light to be incident on a rear side face of the light guide element; and a diffraction lens formed on the rear side face of the light guide element on which the linear transformed light is incident, and condensing the linear transformed light. The light condensed by the lens means is emitted from a front side face of the light guide element onto a road surface in front of the vehicle.

A light projection method for a moving body which is performed by a processor of the moving body is provided. The method comprises: irradiating light from a light source of the moving body; scanning the light irradiated from the light source with an angle range that is formed by swing a mirror portion of an optical scanner of the moving body; acquiring change information of the angle range at which the mirror portion swings; changing the angle range at which the mirror portion swings based on the acquired change information; and changing an irradiation range of the light irradiated from the light source.

Systems and methods of providing a DOT Lighting monitor that automatically detects when any of the exterior lights on a commercial motor vehicle fails/burns out and that alerts the driver to which one(s) is affected is provided. Each required light is monitored, and a state of an indicator corresponding to that required light is changed to notify an operator of a failure thereof.

A vehicular forward viewing image capture system includes an accessory module configured for attachment at an in-cabin side of a windshield of a vehicle, whereby a CMOS image sensor views through the windshield forward of the equipped vehicle. With the accessory module attached at the in-cabin side of the windshield, and while the vehicle is traveling along a road, captured image data is processed to determine (i) presence of an object of interest viewed by the image sensor and (ii) location and/or movement of the object of interest viewed by the image sensor. Multiple frames of captured image data are processed in determining location and/or movement of the object of interest. Image data captured by the image sensor is processed for an automatic headlamp control system of the equipped vehicle. The vehicular forward viewing image capture system automatically compensates for misalignment of the image sensor.