A method for the automatic adjustment of an angle of inclination of a vehicle headlight, having the steps: continuous measurement of a rate of rotation of the vehicle headlight; calculation of a change of a gravitational acceleration vector of the vehicle headlight in the coordinate system of the vehicle headlight, using the measured rate of rotation; calculation of an angle of inclination correction using the change of the gravitational acceleration vector; and adjustment of the angle of inclination of the vehicle headlight using the angle of inclination correction.

A light-distribution control apparatus includes a light-distribution changer configured to change distribution of light that a headlamp of the vehicle emits toward a region in front of the vehicle, a data acquirer, an attitude sensor, and a brake sensor, a light-distribution control processor. The light-distribution control is configured to control the light-distribution changer based on one or more pieces of the data acquired from the data acquirer, the attitude data acquired from the attitude sensor, and the internal pressure data acquired from the brake sensor. The light-distribution control processor is configured to control the light-distribution changer based on the internal pressure data.

There is provided a lighting device capable of forming a line beam having a sufficiently long length in an irradiation direction. A distance between a light source end close to irradiation surface and irradiation surface is greater than a distance between lens center and irradiation surface by using light source in which a plurality of light emitters is arranged in a straight line and lens of which an emission surface having a constant curvature is corrected by an odd function. Accordingly, a shape of light source is formed on irradiation surface, and thus, it is possible to form line beam having the sufficiently long length in the irradiation direction.

A lamp device for a vehicle includes a lamp housing and a light-emitting unit disposed therein. The light-emitting unit includes a light-emitting surface adjustable in at least one of a shape, an intensity of illumination, or a color of illumination. The lamp device further includes a bracket that supports the light-emitting unit to be mounted in the lamp housing, and that is configured to change the shape of the light-emitting surface of the light-emitting unit. The lamp device further includes a driving unit configured to apply a driving force to the bracket that changes the shape of the light-emitting surface of the light-emitting unit. The lamp device is configured to at least partially change, based on a plurality of lighting modes, at least one of the shape of the light-emitting surface, the intensity of illumination emitted from the light-emitting surface, or the color of illumination emitted from the light-emitting surface.

A lamp for a vehicle includes a laser diode configured to output light, an interface configured to communicate with a brake device of the vehicle, and at least one processor coupled to the interface and configured to receive brake operation information from the brake device via the interface, and control a light output of the laser diode based on the brake operation information.

An optical axis control apparatus is provided with a relative-road-surface-angle calculating unit which calculates a relative horizontal plane angle being an inclination angle of a vehicle with respect to a horizontal plane by using an output value of an acceleration sensor provided on the vehicle and calculates a relative road surface angle being an inclination angle of the vehicle with respect to a road surface by integrating an amount of change of the relative horizontal plane angle while the vehicle is stationary, a relative-road-surface-angle correcting unit which obtains braking information indicating an operation state of a brake device provided on the vehicle and corrects the relative road surface angle for a change in the braking information, and an optical axis control unit which controls an optical axis of headlights provided on the vehicle using the relative road surface angle corrected by the relative-road-surface-angle correcting unit.

To provide a technique capable of accurately obtaining the attitude of a vehicle in the pitch direction. A device controls the optical axis of a vehicular lamp in accordance with an attitude change in pitch direction of the vehicle having (a) an angle calculation part which obtains acceleration associated with the vertical and the horizontal direction at a predetermined time interval, obtains a first and a second acceleration related to the vertical and the horizontal direction by eliminating the gravitational acceleration component from each acceleration, calculates a vehicle traveling direction acceleration based on the two accelerations, and obtains a vehicle attitude angle based on a correlation between the acceleration and the vehicle traveling direction acceleration, and (b) an optical axis setting part which generates a control signal for controlling the optical axis of the lamp based on the vehicle attitude angle, and provides the control signal to the lamp.

A vehicular lighting assembly for compensating for the change in light emission angle due to load on a vehicle. The assembly included at least one lighting element, an actuator associated with the or each lighting element for adjusting a light emission angle of light emitted therefrom relative to the vehicle with which the vehicular lighting assembly is associated, and an actuator housing in which the actuator is housed. A vehicular-pitch-determining sensor is then arranged to indirectly determine a pitch of the vehicle, and associated with a controller for controlling an actuation of the actuator in response to a vehicular pitch as determined by the vehicular-pitch-determining sensor. A vehicular lighting system, pitch-compensation actuation unit, motor vehicle and method of altering the angle of light emission from the headlamps of a motor vehicle are also provided.

The invention relates to a method for controlling a luminous device of a motor vehicle arranged to emit a pixelated light beam in a preset emission region. The method includes receiving an instruction to emit a desired pixelated luminous function for each of the luminous modules. The instruction for creating a digital image forming one segment of the desired pixelated luminous function in a frame corresponding to the preset emission region of the luminous module, the digital image being independent of the types of light sources and of optical device of the luminous module. The method further correcting said created digital image depending on the types of light sources and of optical device of the luminous module. The method additionally emitting, with the luminous module, into the preset emission region, a pixelated light beam corresponding to the corrected digital image.

A headlamp for vehicles that has a light source unit. Numerous light sources and/or light guides are controllable individually. A sensor unit for detects headlamp status data and/or vehicle environment data. A control unit for controlling the light sources and/or light guides generates a predefined light distribution for the headlamp. The range of the headlamp can be adjusted on the basis of sensor signals from the sensor unit. The control unit contains a control element for the light sources and/or light guides for projecting a guide marking onto a road surface. The control unit contains a compensator that compensates for deviations in the guide marking on the basis of a sensor signal generated by the sensor unit.