A vehicle comprises a first lighting assembly disposed to the left of a longitudinal axis of the vehicle and comprising a first array of independently operable light emitting diodes and a first projection lens arranged to form a front left light beam for the vehicle from light output from the first array of light emitting diodes, a second lighting assembly disposed to the right of the longitudinal axis of the vehicle and comprising a second array of independently operable light emitting diodes and a second projection lens arranged to form a front right light beam for the vehicle from the second array of light emitting diodes, and a controller configured to control activation of the light emitting diodes in the first array of light emitting diodes to adjust an angle between the front left light beam and the longitudinal axis of the vehicle and to control activation of the light emitting diodes in the second array of light emitting diodes to adjust an angle between the front right light beam and the longitudinal axis of the vehicle.

An illumination device for a motorcycle headlamp, which device is configured to create a segmented light pattern and includes: (i) a plurality of light sources, at least some of which are configured to be activated independently from each other, (ii) a segmented light guide unit, including a plurality of light guide elements and a light homogenization body, and (iii) a projection lens, which is configured to receive the light emitted from the collective light exit surface of the light homogenization body and to project the segmented light pattern, wherein at least some of the light guide elements are part of a first group of light guide elements, said first group having a defined geometric shape of the light entry surface, which is limited by four corners connected by four side edges (left, right, lower, and upper) wherein three of the side edges are straight, and the fourth edge has a rounded protrusion, which increases the light entrance surface, and is either the left or the right edge of the respective light guide element.

The present disclosure relates to a device for controlling a lamp for a vehicle. The device may include a lamp controller that determines whether to change a light range control code based on at least one of image information, map information, or illuminance information of a front region of the vehicle, and determines increase or decrease and an increase or decrease amount of the light range control code based on steering information, and a lamp for expanding or reducing a light irradiation range based on the light range control code.

The present disclosure relates to a device for controlling a lamp for a vehicle. The device may include a lamp controller that determines whether to change a light range control code based on at least one of image information, map information, or illuminance information of a front region of the vehicle, and determines increase or decrease and an increase or decrease amount of the light range control code based on steering information, and a lamp for expanding or reducing a light irradiation range based on the light range control code.

An illumination system for a vehicle includes a headlight configured to emit a light beam along an optical path and into an environment. The illumination system includes an optical element having a body comprising four sides. The optical element is positioned along the optical path and configured to redirect the light beam. The illumination system includes a front lens positioned along the optical path and configured to receive the light beam from the optical element and collimate the light beam as the light beam passes into the environment. The optical element is configured to move around an optical element axis to translate the light beam relative to an azimuth plane of the environment.

The present invention relates to a headlamp control system. The front headlamp control system and a control method thereof according to the present invention are highly applicable to existing vehicles and are capable of efficiently controlling light of a front headlamp by adjusting a light quantity of the front headlamp based on a combination of navigation information and camera information in addition to a steering angle of a steering wheel, and are capable of increasing visibility of an area in front of a driver by calculating a light-off section in a case where there is a preceding vehicle and increasing, in a case where a changed position of a high luminance region overlaps the light-off section, a range of a central luminance region in a horizontal direction or a vertical direction to maintain the high luminance region.

The present invention relates to a headlamp control system. The front headlamp control system and a control method thereof according to the present invention are highly applicable to existing vehicles and are capable of efficiently controlling light of a front headlamp by adjusting a light quantity of the front headlamp based on a combination of navigation information and camera information in addition to a steering angle of a steering wheel, and are capable of increasing visibility of an area in front of a driver by calculating a light-off section in a case where there is a preceding vehicle and increasing, in a case where a changed position of a high luminance region overlaps the light-off section, a range of a central luminance region in a horizontal direction or a vertical direction to maintain the high luminance region.

The present disclosure relates to a dynamic bending ADB head lamp system and a method for controlling the same that, in an ADB or a high beam operation of a vehicle equipped with a head lamp of a matrix type having an ADB function, may move a central region of a high beam in a direction of a movement of the vehicle in response to a change in a steering angle of the vehicle to improve visibility of a driver, and move the central region of the high beam by changing only a current value without a separate driving motor to reduce a manufacturing cost.

A vehicle illumination system provided in a vehicle capable of traveling around a corner by inclining a vehicle body toward a turning direction includes: a headlamp mounted on a front portion of the vehicle; a communication lamp disposed on the vehicle body in a region adjacent to the head lamp so as to be visible from ahead of the vehicle; and an illumination control unit configured to change a lighting mode of the communication lamp depending on a state of the vehicle.

Provided is a vehicle headlight device which can improve overlooking of pedestrians by a drive, even under adverse conditions such as nighttime or rain at night. A vehicle headlight device includes: a pattern photoirradiator (right-side pattern irradiation lamp) which irradiates light on a predetermined irradiation pattern light distribution region of a vehicle in an irradiation pattern in which a bright region and a dark region are alternately repeated; and a cornering light which irradiates a light distribution region under the irradiation pattern light distribution region in a form in which an entire area is a bright region. In this embodiment, the pattern photoirradiator irradiates light synchronously with the cornering light.