A vehicle head light control apparatus controls a lighting apparatus included in a headlight of a vehicle to avoid irradiating to an irradiation avoidance region which is a region overlaps with a detected object. The lighting apparatus can irradiate an irradiation region which is a set of irradiation sections. When the vehicle is in a manual driving state, irradiating to the irradiation sections included in an adjacent region which is a region adjacent to the irradiation avoidance region is reduced as a distance between the irradiation section and the irradiation avoidance region becomes shorter. When the vehicle is in an autonomous driving state, the adjacent region is not provided or the adjacent region becomes smaller as compared with a case where the vehicle is in the manual driving state.

An optical light beam projection device, notably for a motor vehicle, includes upstream in the direction of propagation of the light rays, a set of at least two associated submatrices each provided with primary light sources capable of emitting light rays. Downstream, a primary optical system is provided with a plurality of convergent optics, at least one convergent optic being associated with each submatrix and arranged downstream thereof, the separation between the optical axes of two adjacent convergent optics corresponds respectively to the separation between the centers of the corresponding adjacent submatrices. Another subject of the invention is an optical module comprising the device and a motor vehicle headlight.

A vehicle head light control apparatus controls a lighting apparatus included in a headlight of a vehicle to avoid irradiating to an irradiation avoidance region which is a region overlaps with a detected object. The lighting apparatus can irradiate an irradiation region which is a set of irradiation sections. When the vehicle is in a manual driving state, irradiating to the irradiation sections included in an adjacent region which is a region adjacent to the irradiation avoidance region is reduced as a distance between the irradiation section and the irradiation avoidance region becomes shorter. When the vehicle is in an autonomous driving state, the adjacent region is not provided or the adjacent region becomes smaller as compared with a case where the vehicle is in the manual driving state.

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 light device comprises a laser light source, a primary optical system with at least one diffractive and/or at least one reflective optical element to convert monochromatic coherent light to a collimated beam of coherent light, a MOEMS comprising one or more micro-mirrors to route coherent light and convert it to white light, and a secondary optical system comprising at least one diffractive and/or at least one reflective optical element to direct white light from the light device to create a light pattern on the display surface and/or in specific zones in front of the vehicle. It further comprises an electromagnetic control system connected to the MOEMS and the light source to control changes of rotation angle, oscillation angle and oscillation rate and frequency of one of the micro-mirrors, and to control the light source activity, for controlled changing of the shape and/or position of the light pattern depending on current conditions of the vehicle.

A vehicle headlight has a segmented light guide device in which segments are selectively controlled to operate in an output state that reduces glare to oncoming vehicle drivers. Vehicle sensors and controller circuitry are used to identify areas of glare removal in the light pattern of the headlight and control the corresponding segments in the light guide device to operate in a selected light output state that reduces glare. The segments can be operated in a focused output state for vehicle driver visibility, or in a scattered output state to reduce glare. The segments can be operated in a clear or transparent output state for vehicle driver visibility, or in a reflected output state to reduce glare. Reflected light can optionally be re-directed. The light guide device can employ bi-stable liquid crystal shuttering or liquid crystal switchable mirror technology.

Disclosed is a condenser and a high-and-low-beam integrated vehicle lamp module, the condenser comprises at least one light incident portion, a light-transmitting portion, and a light emergent portion, wherein a 50L dark area light shape forming structure is formed on the light-transmitting portion; the 50L dark area light shape forming structure protrudes from a surface of the light-transmitting portion and has a slope surface; and the distance from the slope surface to the surface of the light-transmitting portion gradually increases from a position close to the light incident portion to the light emergent portion. Since the 50L dark area light shape forming structure protrudes out of the surface of the light-transmitting portion and has the slope surface, in a high-beam illumination mode, some light is emitted from the 50L dark area light shape forming structure to a 50L test point.

A light device comprises a laser light source, a primary optical system with at least one diffractive and/or at least one reflective optical element to convert monochromatic coherent light to a collimated beam of coherent light, a MOEMS comprising one or more micro-mirrors to route coherent light and convert it to white light, and a secondary optical system comprising at least one diffractive and/or at least one reflective optical element to direct white light from the light device to create a light pattern on the display surface and/or in specific zones in front of the vehicle. It further comprises an electromagnetic control system connected to the MOEMS and the light source to control changes of rotation angle, oscillation angle and oscillation rate and frequency of one of the micro-mirrors, and to control the light source activity, for controlled changing of the shape and/or position of the light pattern depending on current conditions of the vehicle.

To obtain a liquid crystal element having a plurality of alignment domains with a simple configuration. A manufacturing method of a liquid crystal element including: a first process that forms a first substrate having a first alignment film subjected to uniaxial alignment treatment; a second process that forms a second substrate having a second alignment film subjected to uniaxial alignment treatment; a third process that forms a liquid crystal layer between the first alignment film and the second alignment film using a liquid crystal material including a monomer which can be polymerized by light irradiation; and, of a first region and a second region adjacent to each other in the liquid crystal layer in a plane view, a fourth process that performs light irradiation with no voltage applied or with a voltage less than a threshold value applied to the first region.

The invention relates to an optical device for projecting light beams, capable of cooperating with a pixelated light source, including a plurality of selectively activatable emissive elements, which consists of the following components, arranged in succession along the path of the light rays from the source: a convergent first lens, a divergent or neutral second lens, a pupil and a convergent third lens.