Systems and methods for automated headlamp adjustments for autonomous vehicles are disclosed. In one aspect, an autonomous vehicle includes at least one headlamp configured to generate and emit light to illuminate an environment of the autonomous vehicle, at least one actuator configured to adjust a direction in which the light is emitted from the at least one headlamp, and at least one perception sensor configured to generate perception data based at least in part on the light emitted from the at least one headlamp. The autonomous vehicle further includes a processor configured to receive one or more inputs including a navigational map, determine a headlamp angle based at least in part on the navigational map, and provide a command to the at least one actuator to adjust an orientation of the at least one headlamp based on the headlamp angle.

A headlight assembly for an automobile illuminates a path of the automobile while executing a turn. The assembly includes at least one primary light source, a means of determining an orientation of the automobile, the means being configured to generate a first signal when the orientation is varied, a means of determining an orientation of a steering device of the automobile, the means being configured to generate a second signal when the orientation of the steering device is varied, and a control unit configured to receive and condition the first and the second signal to produce a conditioned signal; and at least two secondary light sources, wherein at least one of the at least two secondary light sources is actuated by the conditioned signal transmitted from the control unit. The invention also describes a method for illuminating a path of the automobile while executing a turn.

A headlight system for a banking vehicle is provided. The headlight system includes a plurality of optical assemblies being arranged about an optical horizon and an optical vertical axis. Each of the plurality of optical assemblies includes an illumination source and an optical element. Each of the illumination sources is configured to direct light toward a corresponding one of the optical elements to produce an illumination region. The illumination regions combine to form an illumination pattern that includes at least one illumination region that is radial and is positioned relative an optical origin. The intersection between the optical horizon and the optical vertical axis defines the optical origin.

A vehicle detecting device includes a region setting unit that sets a plurality of regions of interest having different ranges on image data acquired from an image capturing device that captures an image of a space in front of a host vehicle; and a vehicle determining unit that determines, for each of the regions of interest, presence of a front vehicle based on a luminous point present in the region and that executes a determination at different frequencies in the respective regions of interest.

The angle-adjusting vehicular headlights comprise a housing, a swivel bracket, a distance checker, a tilt mechanism, a controller, and a headlight socket. The angle-adjusting vehicular headlights may change an elevation angle of a headlight responsive to a determination by the controller that an inclination angle of a vehicle has changed. As non-limiting examples, the inclination angle may have changed due to a cargo load that has been placed into the vehicle thus compressing the vehicle suspension or the inclination angle may have changed due to the cargo load being removed from the vehicle and the resulting decompression of the vehicle suspension. angle-adjusting vehicular headlights may generally be deployed in pairs.

The present disclosure relates to a headlamp control apparatus including a first determination unit configured to, when information regarding a distance from a speed breaker from a detection device included in a vehicle, determine whether the distance from the speed breaker is smaller than a predetermined first threshold distance; a second determination unit configured to, when information regarding an inclination is received from an inclination detection device included in the vehicle, determine whether the inclination is a predetermined first inclination corresponding to an entry into the speed breaker or a predetermined second inclination corresponding to moving off of the speed breaker; and a control unit configured to control a high-beam lamp or adjusting brightness of the high-beam lamp not to shine forward with respect to when it is determined that the distance from the speed breaker is smaller than the first threshold distance, configured to control a general-beam lamp or adjusting brightness of the general-beam lamp to shine forward and downward with respect to the vehicle when it is determined that the inclination is the first inclination, and configured to control the high-beam lamp and the general-beam lamp to return to previous states thereof when it is determined that the inclination is changed from the first inclination to the second inclination.

A motorcycle light includes a lighting device, having a headlight contained within a housing; a rod configured to engage with a headlight connection of a motorcycle; and one or more wires to engage with an electrical system of the motorcycle; a motor engaged with the housing and to provide rotational movement of the housing relative to the rod; and one or more sensors in electrical communication with the motor and to detect when the motorcycle is at a leaning position, the one or more sensors to provide a command to the motor to rotate the housing to a desired angle for improved visibility.

A method of compensating for a level of a headlamp using a lane departure warning system is provided. The method adjusts a level of a headlamp using a camera of a lane departure warning system. In particular, the method includes calculating, by an LDWS camera, a predetermined irradiation angle of a headlamp and calculating, by the LDWS camera, a cut-off inclination of a low beam in a predetermined distance. Additionally, the method includes driving a lamp actuator when the cut-off inclination is less than a predetermined threshold inclination and re-adjusting the cut-off inclination.

A lighting device is provided for controlling the photometric distribution of light emitted by two or more LEDs. The lighting device may be integrated with a control system of the vehicle and may be controlled by a remote controller. The lighting device may be capable of being operated in one or more modes of operation based on operating conditions, user input, or both. Operating conditions may include vehicle conditions, environmental conditions, and user conditions. The controller may operate a software application to enable the user to modify, control, or otherwise regulate any mode of operation or other feature of the lighting system.

Automated control of one or more exterior aircraft lights is presented, for instance exterior aircraft lights that enhance visibility by a pilot and including landing lights, taxi lights, and runway turnoff lights. One aspect of this automated control is that one or more of such exterior aircraft lights may be automatically activated, for instance when the aircraft has at least initiated movement and has not yet reached a certain altitude (e.g., while the aircraft is taxiing on the ground and including during takeoff). Another aspect of this automated control is that a trained image classification model may determine a visibility classification for an image acquired by an exterior aircraft camera, and this visibility classification may be used to automatically control the operation of one of more of such exterior aircraft lights (e.g., an intensity of the light output from such an exterior aircraft light(s)).