An image projection apparatus that can be attached to a vehicle and can be effectively utilized for acquisition of road surface condition information, detection of a hidden vehicle, and the like is provided. The image projection apparatus that projects an image includes: an acquisition unit that acquires information related to a vehicle; an image projection unit that projects an image based on the information acquired by the acquisition unit; and imaging means that acquires an image outside the vehicle, the image projection unit projects light in a wavelength band centered on a wavelength of 1.4 μm and the imaging means provides the information related to the vehicle by imaging an image projected based on the light in the wavelength band centered on the wavelength of 1.4 μm.

A intelligent headlight system for a bicycle according to an embodiment of the present invention comprises: a bicycle body; a portable terminal which may be carried by a rider of the bicycle body and has a GPS module, for detecting the location information of the bicycle body, so as to measure the running speed on the basis of the location information of the bicycle body; and a headlight apparatus which is disposed on the bicycle body so as to cast light on the scene ahead of the bicycle body, is communicatably connected to the portable terminal so as to receive the running speed of the bicycle body, and is formed such that irradiation patterns may vary in accordance with the running speed of the bicycle body.

The disclosure relates to a method for illuminating a road area by a motor vehicle having the following steps: determining a trajectory relating to a future movement of the motor vehicle on a road, calculating a light distribution for a headlamp of the motor vehicle as a function of the determined trajectory in such a manner that a course of the trajectory is projected onto the road as part of the light distribution, and emitting a brightness distribution corresponding to the light distribution by the headlamp onto the road. In order to facilitate an improved overview of the driving of the motor vehicle, the light distribution is additionally calculated as a function of the determined trajectory in such a manner that, based on the light distribution in addition to the trajectory, an acceleration of the motor vehicle parallel to its longitudinal direction is also symbolized.

An illumination module including a light emitting unit and a first liquid crystal lens is provided. The light emitting unit emits illumination light. The first liquid crystal lens is arranged corresponding to the light emitting unit and receives the illumination light. The first liquid crystal lens is configured to converge, diverge or deflect the illumination light. An illumination device, a vehicle, and a driving method for the illumination device are also provided.

The present disclosure relates to a headlamp leveling system. The headlamp leveling system includes a leveling controller that generates a control code based on information on a location of a speed bump, information on a current location of a vehicle, and information on a vertical level of a rear surface of the vehicle, and a headlamp leveling device for changing a light irradiation angle of a headlamp to a light irradiation angle corresponding to a code value of the control code.

A remotely controllable headlight assembly for use on a vehicle, the assembly comprising a circuit board including a plurality of LEDs including at least a first low beam LED, a first high beam LED and at least one additional LED, optic elements supported adjacent the LEDs on the circuit board, a processor and a remote communication module coupled to the processor, the remote communication module configured to receive commands from a wireless device, wherein the commands instruct the processor to illuminate the at least one additional LED, wherein the processor controls the at least one additional LED based on the received wireless commands.

The disclosure relates to a method for illuminating a road area by a motor vehicle having the following steps: determining a trajectory relating to a future movement of the motor vehicle on a road, calculating a light distribution for a headlamp of the motor vehicle as a function of the determined trajectory in such a manner that a course of the trajectory is projected onto the road as part of the light distribution, and emitting a brightness distribution corresponding to the light distribution by the headlamp onto the road. In order to facilitate an improved overview of the driving of the motor vehicle, the light distribution is additionally calculated as a function of the determined trajectory in such a manner that, based on the light distribution in addition to the trajectory, an acceleration of the motor vehicle parallel to its longitudinal direction is also symbolized.

A method and a device for adjusting a light distribution of a vehicle headlight having a control unit for adjusting the light distribution. The headlight includes a number of light sources. The control unit includes an interface configured for receiving user-specified parameters for adjusting and/or modifying an illuminance distribution within the light distribution.

A vehicle lighting device includes at least one headlight, a position and/or acceleration sensor, and a control unit for adjusting a light/dark boundary of the headlight. Pitch movements of the vehicle can be detected by the position and/or acceleration sensor, and a change in the light/dark boundary due to the respective pitch movement can be compensated for by the control unit. The position and/or acceleration sensor and the control unit are arranged in the headlight or directly on the headlight.

A headlight system for a banking vehicle is provided. The headlight system includes a plurality of optical assemblies being arranged about an optical horizon and an optical vertical axis. Each of the plurality of optical assemblies includes an illumination source and an optical element. Each of the illumination sources is configured to direct light toward a corresponding one of the optical elements to produce an illumination region. The illumination regions combine to form an illumination pattern that includes at least one illumination region that is radial and is positioned relative an optical origin. The intersection between the optical horizon and the optical vertical axis defines the optical origin.