A headlamp control system includes: a headlamp that emits light toward a forward direction of a vehicle; a tilt detection part; and a control part. The headlamp includes: high beam emitting parts that respectively illuminate plural high beam areas arrayed in a left-right direction; and a low beam emitting part that illuminates a low beam area located at a lower position than the plural high beam areas. The control part, in a state where the low beam emitting part is on, when the tilt detection part detects that the vehicle has tilted such that one of left and right sides of the vehicle is lowered than the other one of the left and right sides, controls the high beam emitting parts so as to illuminate at least one of the plural high beam areas, the at least one being on the one of the left and right sides.

A headlamp is configured to emit a low beam toward a forward direction of a vehicle. The headlamp is switchable between a first low beam distribution state and a second low beam distribution state. The headlamp is configured to, in the first low beam distribution state, illuminate a low area straight ahead of the vehicle, and in the second low beam distribution state, illuminate at least one of: a width-direction intermediate portion of the low area, one width-direction end portion of the low area, and the other width-direction end portion of the low area, even brighter than the first low beam distribution state.

A headlight module includes: a light source for emitting light; a condensing optical element for concentrating the light; and an optical element including an incident surface for receiving the concentrated light, a reflecting surface for reflecting the received light, and an emitting surface for emitting the reflected light. The condensing optical element changes a divergence angle of the light to form a light distribution pattern. The reflected light and light that enters the optical element and is not reflected by the reflecting surface are superposed on a plane including a point located at a focal position of the emitting surface in a direction of an optical axis of the emitting surface and being perpendicular to the optical axis, thereby forming a high luminous intensity region in the light distribution pattern on the plane. The emitting surface has positive refractive power and projects the light distribution pattern formed on the plane.

A light projection device for a moving body is provided on the moving body and includes: a light source for irradiating light; an optical scanner which has a mirror portion for reflecting the light irradiated from the light source and a drive source for swinging the mirror portion, and scans the light irradiated from the light source; and a control portion which controls to acquire change information of an angle range at which the mirror portion swings, change the angle range at which the mirror portion swings by controlling the drive source based on the acquired change information, and change an irradiation range of the light irradiated from the light source.

A vehicular forward viewing image capture system includes an accessory module configured for attachment at an in-cabin side of a windshield of a vehicle, whereby the imaging sensor views through the windshield forward of the equipped vehicle. With the accessory module attached at the in-cabin side of the windshield, and while the vehicle is traveling along a road, a control processes captured image data to determine (i) presence of an object of interest viewed by the imaging sensor and (ii) location and/or movement of the object of interest viewed by the imaging sensor. The control, responsive to the processing of captured image data and responsive to vehicle data received via a vehicle communication bus, at least in part provides at least one selected from the group consisting of (a) traffic sign recognition, (b) traffic light status detection, (c) adaptive cruise control and (d) pedestrian detection.

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 working vehicle is capable of autonomously traveling on a target traveling route and appropriately performing illumination during autonomous traveling to enable an operator to reliably confirm the presence of obstacles or the like on the target traveling route. The working vehicle includes a traveling body to autonomously travel on the target traveling route, illumination lamps located on the traveling body to respectively illuminate different directions, and a controller to change a control relating to a way of turning on the illumination lamps during the autonomously traveling.

An illumination device includes at least one light source configured to perform illumination with a plurality of illumination patterns, a detection unit for detecting state information on the state of an illumination target that is to be illuminated by the light source, an arithmetic unit configured to calculate, using a neural network, illumination pattern information for generating an illumination pattern appropriate for the illumination target from the state information, and an illumination control unit configured to control the light source in order to perform illumination with an illumination pattern based on the illumination pattern information.

For vehicles having left and right headlights, a steering direction signal input indicative of a left or right steering direction is used to modulate a control signal of a liquid crystal beam broadening device to broaden horizontally the vehicle headlight beam when the steering direction signal input is indicative of a selected one of a left or a right steering direction and to maintain or reduce a horizontal spread of the vehicle headlight beam when said steering direction signal input is indicative of one of a left or a right steering direction opposite to the selected steering direction.

The light source of the present disclosure spot-irradiates a distant place in front of a vehicle. The turn on/off circuit supplies a driving current I.sub.LD to the light source 120 to turn on the light source. The swivel mechanism swivels the light source. The turn on/off circuit reduces a light quantity of the light source as a swivel angle θ of the swivel mechanism is large.