A bank angle of a vehicle can be accurately calculated using yaw axis data and roll axis data, and based on the calculated bank angle, vehicle illumination optics can be controlled to maintain a pattern of distributed light from the illumination optics to be generally horizontal. The calculated bank angle may be zeroed when the yaw axis data equals zero. The improved pattern of distributed light from the illumination optics illuminates a more natural field of view for the vehicle driver during a bank.

A headlight assembly can include a headlight and one or more actuators operatively positioned to cause the position and/or orientation of the headlight to be adjusted. The one or more actuators include a bladder. The bladder can include a flexible casing. The bladder can define a fluid chamber. The fluid chamber can contain a dielectric fluid. The one or more actuators can include a first conductor and a second conductor operatively positioned on opposite portions of the bladder. The one or more actuators can be configured such that, when electrical energy is supplied to the first conductor and the second conductor, the first conductor and the second conductor can become oppositely charged. As a result, the first conductor and the second conductor are electrostatically attracted toward each other to cause at least a portion of the dielectric fluid to be displaced to an outer peripheral region of the fluid chamber.

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.

The present application relates to a method for controlling a controllable headlight of a motor vehicle, in which the headlight is controlled in such a way that a predefinable light distribution is made available on a traffic route on which the motor vehicle is guided, wherein a profile of the traffic route is determined, and a light output of the headlight is set as a function of the determined profile of the traffic route in order to make available the predefinable light distribution, wherein the light distribution is made available by means of a multiplicity of pixels of a pixel headlight as a controllable headlight, for which purpose the lighting elements which form the pixels are controlled individually with respect to their light output, a region of the traffic route is determined in the direction of travel in front of the motor vehicle, which region is determined to be travelled on by the motor vehicle and is correspondingly bounded laterally, and the lighting elements are controlled in such a way that exclusively the region is illuminated with the predefinable light distribution.

A motorcycle includes a pair of left and right front forks, a headlight, cover members (side cowls and light covers), and camera units. A front wheel is rotatably attached to the pair of left and right front forks. The headlight irradiates a forward side. The cover members each having an internal space are disposed at least laterally outside the pair of left and right front forks in a front view. The camera units detect the forward side by acquiring visible light which is one kind of electromagnetic waves (by acquiring images). In a front view, the camera units are disposed below the headlight and laterally outside the pair of left and right front forks. The camera units are disposed in the internal spaces of the cover members.

A lighting system and method of operating the same for a vehicle having a vehicle structure includes a plurality of primary low beam elements and a plurality of secondary low beam elements. The system further includes a primary high beam element and a secondary high beam element. A lean angle sensor is coupled to the vehicle structure. A controller is coupled to the lean angle sensor controlling the primary low beam elements, the secondary low beam element and the secondary high beam element in response to the lean angle.

Vehicle lamp controllers, methods for controlling vehicle lamps and vehicle lamp systems including the lamp controller and the lamps can be configured to detect whether a traveling road is a straight road or a curved road. When the traveling road is the curved road, the lamp system can direct light distribution patters from an initially light distribution angle along the traveling road with reference to a first threshold. When the traveling road is the straight road, the lamp system can direct light distribution patters from the initially light distribution angle along the traveling road with reference to a second threshold, which is larger than the first threshold. The second threshold can be changed so as to maintain preferable light distribution patterns. Thus, the present invention can provide the vehicle lamp controllers, the controlling methods for the vehicle lamps and the vehicle lamp system to form the preferable light distribution patterns.

An adaptive light beam unit attachable to a vehicle including: At least one light engine assembly, wherein the at least one light engine assembly includes at least one light engine, the at least one light engine includes at least one light source and at least one reflector adapted to reflect light emitted from the at least one light source to form a light beam; At least one sensor for measuring angle of rotation of the vehicle; At least one motor connected to the at least one light engine assembly for changing a projection angle of the light beam; At least one controller operatively connected to the least one light engine assembly and the at least one sensor, whereby the at least one controller receives information on the angle of rotation of the vehicle, and drives the at least one electrical motor to maintain or alter the projection angle of the light beam such that a desired lighting positioning is obtained based on a pre-determined scenario.

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 bank angle of a vehicle can be accurately calculated using yaw axis data and roll axis data, and based on the calculated bank angle, vehicle illumination optics can be controlled to maintain a pattern of distributed light from the illumination optics to be generally horizontal. The calculated bank angle may be zeroed when the yaw axis data equals zero. The improved pattern of distributed light from the illumination optics illuminates a more natural field of view for the vehicle driver during a bank.