The invention relates to a method for controlling a motor vehicle headlight which at least comprises a laser diode (1) and a light conversion element (8) paired with the laser diode (1). Light conversion element (8) regions corresponding to different regions of the light image (11) can be illuminated periodically and with a varying intensity by means of a light beam (2) of the laser diode (1), and the illumination intensity in the light conversion element (8) regions corresponding to the different regions of the light image (11) is adjusted simultaneously by both the relative illumination duration of the different regions as well as different luminous intensities of the laser diode (1) in the light conversion element (8) regions corresponding to the different regions of the light image (11). In regions in which the light beam (2) is moved with an angular speed below a defined value for the angular speed, the laser diode (1) is solely deactivated and activated, and different luminous intensities of the laser diode (1) are set when the angular speed is above a defined value. The motor vehicle headlight according to the invention has a computing unit (4) for carrying out the method according to the invention.

A headlamp apparatus may include: a light source configured to emit light; a reflector having a reflecting surface with different curvatures in first and second directions crossing each other, and configured to reflect the light emitted from the light source; and a lens configured to receive the light through the reflector, and change the magnification of the light so as to guide the light to the front.

A lighting device, including an array of at least two light sources of the light emitting semiconductor type and an array of at least a first illumination element and a second illumination element, each illumination element being associated with one of the light sources and configured for being lit the associated light source in such a way that a light beam emitted by the light source exhibits a shape dependent on a shape of the illumination element, the first illumination element being of trapezoidal shape having a large base and the second illumination element having a shape partially complementary to the trapezoidal shape and including two edges extending from two opposite ends of the large base, parallel with each other, being distant by at least a length of the order of the length of the large base.

A vehicle headlamp unit for irradiating light in front of the vehicle with a high contrast ratio and is capable of sufficiently cutting off the illumination light is provided. The unit includes a light source, a parallel optical system that produces parallel light, a polarizing beam splitter that splits light emitted from the parallel optical system into two polarized beams having polarization directions orthogonal to each other, a reflection-type liquid crystal element capable of switching between a first state where the light emitted from a first surface of the polarizing beam splitter is reflected without rotation of the polarization direction, and a second state where the light is reflected with rotation of the polarization direction, in each predetermined section, and a projection optical system that projects light, reflected by the reflection-type liquid crystal element and passed through the polarizing beam splitter once again, in front of the vehicle.

A vehicle headlamp unit for irradiating light in front of the vehicle with a high contrast ratio and is capable of sufficiently cutting off the illumination light is provided. The unit includes a light source, a parallel optical system that produces parallel light, a polarizing beam splitter that splits light emitted from the parallel optical system into two polarized beams having polarization directions orthogonal to each other, a reflection-type liquid crystal element capable of switching between a first state where the light emitted from a first surface of the polarizing beam splitter is reflected without rotation of the polarization direction, and a second state where the light is reflected with rotation of the polarization direction, in each predetermined section, and a projection optical system that projects light, reflected by the reflection-type liquid crystal element and passed through the polarizing beam splitter once again, in front of the vehicle.

A vehicle headlamp unit for irradiating light in front of the vehicle with a high contrast ratio and is capable of sufficiently cutting off the illumination light is provided. The unit includes a light source, a parallel optical system that produces parallel light, a polarizing beam splitter that splits light emitted from the parallel optical system into two polarized beams having polarization directions orthogonal to each other, a reflection-type liquid crystal element capable of switching between a first state where the light emitted from a first surface of the polarizing beam splitter is reflected without rotation of the polarization direction, and a second state where the light is reflected with rotation of the polarization direction, in each predetermined section, and a projection optical system that projects light, reflected by the reflection-type liquid crystal element and passed through the polarizing beam splitter once again, in front of the vehicle.

A vehicle headlamp unit for irradiating light in front of the vehicle with a high contrast ratio and is capable of sufficiently cutting off the illumination light is provided. The unit includes a light source, a parallel optical system that produces parallel light, a polarizing beam splitter that splits light emitted from the parallel optical system into two polarized beams having polarization directions orthogonal to each other, a reflection-type liquid crystal element capable of switching between a first state where the light emitted from a first surface of the polarizing beam splitter is reflected without rotation of the polarization direction, and a second state where the light is reflected with rotation of the polarization direction, in each predetermined section, and a projection optical system that projects light, reflected by the reflection-type liquid crystal element and passed through the polarizing beam splitter once again, in front of the vehicle.

A lamp for a vehicle that radiates a beam pattern to a vehicle front side is provided. The lamp for a vehicle includes at least one light source and a lens configured to radiate a low beam to a front side of the vehicle through refraction of light emitted from the at least one light source. The lens includes a light incident portion that light emitted from the light source is incident and a light exit portion from that refracts and exits the light. The light exit portion includes a plurality of facets formed to have independent curvatures to refract the light from the light source and to form a beam pattern of the low beam. The portions of the plurality of facets are inclined with respect to a virtual vertical line having at least portions of boundary lines formed between the inclined facets and the neighboring facets.

A lamp for a vehicle that radiates a beam pattern to a vehicle front side is provided. The lamp for a vehicle includes at least one light source and a lens configured to radiate a low beam to a front side of the vehicle through refraction of light emitted from the at least one light source. The lens includes a light incident portion that light emitted from the light source is incident and a light exit portion from that refracts and exits the light. The light exit portion includes a plurality of facets formed to have independent curvatures to refract the light from the light source and to form a beam pattern of the low beam. The portions of the plurality of facets are inclined with respect to a virtual vertical line having at least portions of boundary lines formed between the inclined facets and the neighboring facets.

A lighting apparatus for vehicles with a number of semiconductor-based light sources and a projection device for generating the specified light distribution with a cut-off line. The projection device features a correction device with at least two lenses. The surface of at least one of the lenses is designed as a diffractive lens surface for achromatization in a visible wavelength range. The two lenses are made from different lens materials. The surfaces of at least two lenses are designed as refractive lens surfaces that have their optical power calculated based on a temperature range and/or expansion coefficient of the lens material of at least two lenses such that adding the optical power of the lenses yields a predefined total optical power of the correction device.