An imaging system for a vehicle is disclosed. The imaging system comprises an imager configured to capture image data in a forward directed field of view relative the vehicle and an inertial sensor configured to measure a bank angle of the vehicle. A controller is in communication with the imager and the inertial sensor. The controller is configured to receive the image data comprising an imaging area and process the image data with enhanced sensitivity in at least one processing window within the imaging area. The controller is further configured to adjust a location of the processing window within the imaging area based on the bank angle and detect an object in the processing window.

The active lighting device of a bicycle includes a first optical system with a first light source for long-distance illumination, controlled by a control unit, and a second optical system with a second light source for short-distance illumination, controlled by the control unit. It includes a light sensor for determining the light intensity of a location in which the bicycle is situated and allows the control unit to adapt the light intensity of the light sources, if they are activated and if the ambient light intensity is below a determined light threshold. Moreover, a speed sensor is provided for determining the speed of the bicycle in use on a path, so that the control unit controls the activation of the first light source from at least one determined speed threshold. An orientation detector is provided for orienting the light sources depending on a curve travelled by the bicycle in use.

A headlight for a single-track motor vehicle has a support part, a light module which is connected to the support part, a first bearing device, a second bearing device, and a coupling device. The light module is mounted by the first bearing device in a rotatable manner about a first main axis relative to the support part and by the second bearing device in a rotatable manner about a second main axis perpendicular to the first main axis. The coupling device couples the light module to the support part such that the light module is rotated about the second main axis during a rotation about the first main axis.

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.

An active lighting device of a bicycle includes a first optical system with a first light source arrangement for long-distance illumination, which is controlled by a control unit, and a second optical system with a second light source arrangement for short-distance illumination, which is controlled by the control unit. A light sensor determines the light intensity of a location of the bicycle and allows the control unit to adapt the light intensity of the light sources, if they are activated and if the ambient light intensity is below a threshold. A speed sensor determines the speed of the bicycle, so that the control unit controls the activation of the light sources of the first light source arrangement from a speed threshold. An orientation or inclination detector selects and adjusts the light intensity of light sources.

A headlight device for a saddled vehicle includes an LED light source and a mechanism which enlarges an illumination range upward in a turning direction at the time of turning traveling. The mechanism includes, at a position on an outer side, in the vehicle width direction, of a high-beam reflector that reflects forward emitted light from a high-beam, an outer reflection section that reflects the emitted light further upward than the direction of emission of the high-beam reflector. The outer reflection section is provided on at least one of left and right high-beam reflectors, and is configured to be covered by an extension serving as a decorative part, in front view of the vehicle body.

A vehicle lamp tool providing a controller which calculates the luminance distribution of light distribution pattern, an optical device which generates light distribution pattern in an illuminatable area D and a first driving circuit which drives the optical device. The controller transmits a first light distribution correction signal for correcting the inclination of a current light distribution pattern to the first driving circuit if the inclination angle of a vehicle with respect to vertical direction indicated by a detection signal received from a vehicle height sensor is equal to or less than a threshold value. The first driving circuit transmits a first correction driving signal based on the first light distribution correction signal to the optical device. The optical device drives an LD and a light deflector to correct the current light distribution pattern.

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.

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 remotely controllable headlight assembly for use on a vehicle, the assembly comprising a circuit board including a plurality of LEDs including at least a first low beam LED, a first high beam LED and at least one additional LED, optic elements supported adjacent the LEDs on the circuit board, a processor and a remote communication module coupled to the processor, the remote communication module configured to receive commands from a wireless device, wherein the commands instruct the processor to illuminate the at least one additional LED, wherein the processor controls the at least one additional LED based on the received wireless commands.