A control device may include a sensing unit configured to sense a topographical state of a road surface on which a vehicle is travelling. The control device may also include at least one processor configured to, based on the topographical state of the road surface being a first topographical state, control a head lamp of the vehicle to be in a first output state that outputs light to a first area ahead of the vehicle. The at least one processor may also be configured to, based on the topographical state of the road surface changing to a second topographical state different from the first topographical state, control the head lamp of the vehicle to change to a second output state that maintains the output of the light to the first area ahead of the vehicle.

A lighting system for a vehicle is disclosed. The lighting system comprises an imager configured to capture image data in a plurality of image frames in a rearward field of view. The system further comprises at least one headlamp configured to output an emission of light at a plurality of elevations and a controller. The controller is in communication with the imager and the headlamp. The controller is operable to process the image data to identify features in a first frame and a second frame. The controller is further operable to identify a movement of the features from the first frame to the second frame and adjust the elevation of the output emission in response to the movement.

A lighting system for a vehicle is disclosed. The lighting system comprises an imager configured to capture image data in a plurality of image frames in a rearward field of view. The system further comprises at least one headlamp configured to output an emission of light at a plurality of elevations and a controller. The controller is in communication with the imager and the headlamp. The controller is operable to process the image data to identify features in a first frame and a second frame. The controller is further operable to identify a movement of the features from the first frame to the second frame and adjust the elevation of the output emission in response to the movement.

A vehicle lamp system includes a vehicle lamp, a first imaging device structured to be disposed outside a lamp room, and generate a first image, a second imaging device structured to be housed in the lamp room, and generate a second image, and a light distribution control device. The light distribution control device includes an information processor structured to acquire from an outside or generate information of a first light shielding part, and decide a second light shielding part, a control executer structured to execute light distribution control for forming a light distribution pattern including the second light shielding part, and a control regulator structured to control the vehicle lamp to form a light distribution pattern including the first light shielding part when at least one condition of a condition (i) to a condition (iv).

A method for controlling the light distribution of vehicle headlights using vehicle-to-X communication, as well as a vehicle having an electronic circuit that executes such a method. The method can be used to implement a variable light distribution of vehicle headlights without cameras and digital maps.

A method for controlling the light distribution of vehicle headlights using vehicle-to-X communication, as well as a vehicle having an electronic circuit that executes such a method. The method can be used to implement a variable light distribution of vehicle headlights without cameras and digital maps.

Provided are: an inclination angle calculating unit for calculating, when having determined that a vehicle is stationary by referring to vehicle information indicating a traveling state of the vehicle, an inclination angle of the vehicle during a stationary period using inclination angle information indicating an inclination angle of the vehicle and determining a vehicle inclination angle during the stationary period from the calculated inclination angle of the vehicle; and a correction determination processing unit for determining whether an absolute value of a difference between the determined vehicle inclination angle and a reference angle determined previously by the inclination angle calculating unit is less than a first threshold value (threshold value α) and, if the absolute value of the difference is less than the first threshold value (threshold value α), performing a correction to rewrite the vehicle inclination angle to the reference angle.

A vehicle headlamp aiming adjustment system includes a headlamp controller configured to adjust an emission direction of light emitted from a headlamp; a sensing unit configured to measure a sensing area on a ground and measure a change of the sensing area; and a controller configured to receive information about the sensing area measured by the sensing unit, compare the measured sensing area with a pre-stored reference area, and transmit a control signal to the headlamp controller such that the emission direction of light is adjusted in accordance with a change of the sensing area when the sensing area is different from the reference area. The above-describe vehicle headlamp aiming adjustment system can check an emission area of light of a headlamp and secure the driver's field of view by correcting the emission area

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.

A vehicle lamp controller, a vehicle lamp system, and a vehicle lamp control method are provided. The vehicle lamp system includes an acceleration sensor, a vehicle lamp, and the vehicle controller. The controller includes a receiver configured to receive an acceleration information detected by the acceleration sensor, a control unit configured to derive a vehicle longitudinal direction acceleration and a vehicle vertical direction acceleration from the acceleration information, and to generate a control signal for instructing an adjustment of an optical axis of the vehicle lamp, based on a variation in a ratio between a temporal change amount of the vehicle longitudinal direction acceleration and a temporal change amount of the vehicle vertical direction acceleration during at least one of an acceleration and a deceleration of a vehicle, and a transmitter configured to transmit the control signal to an optical axis adjusting portion of the vehicle lamp.