An orientation detection device obtains a detection information of a sensor that detects a displacement in the vertical direction occurring in the vehicle, computes a pitch angle of the vehicle on the basis of the detection information, obtains a gradient information indicating a gradient of a road on which the vehicle travels, and corrects a correlation between the detection information used in computation and the pitch angle on the basis of the gradient information.

A luminous device for a motor vehicle, said device including a pixelized light source and an optical system that is arranged to project a pixelized light beam emitted by the pixelized light source, the optical system comprising a first mirror arranged to collect and reflect rays of the pixelized light beam emitted by the pixelized light source, a second mirror arranged to reflect the rays reflected by the first mirror, and a third mirror arranged to receive the rays reflected by the second mirror and to reflect these received rays so as to correct field aberrations. The invention enables improved projection of a pixelized light beam by a luminous motor-vehicle device.

A vehicular lighting assembly for compensating for the change in light emission angle due to load on a vehicle. The assembly included at least one lighting element, an actuator associated with the or each lighting element for adjusting a light emission angle of light emitted therefrom relative to the vehicle with which the vehicular lighting assembly is associated, and an actuator housing in which the actuator is housed. A vehicular-pitch-determining sensor is then arranged to indirectly determine a pitch of the vehicle, and associated with a controller for controlling an actuation of the actuator in response to a vehicular pitch as determined by the vehicular-pitch-determining sensor. A vehicular lighting system, pitch-compensation actuation unit, motor vehicle and method of altering the angle of light emission from the headlamps of a motor vehicle are also provided.

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 vehicle lighting device includes at least one headlight, a position and/or acceleration sensor, and a control unit for adjusting a light/dark boundary of the headlight. Pitch movements of the vehicle can be detected by the position and/or acceleration sensor, and a change in the light/dark boundary due to the respective pitch movement can be compensated for by the control unit. The position and/or acceleration sensor and the control unit are arranged in the headlight or directly on the headlight.

A vehicle-lamp control device includes a control unit that adjusts an optical axis with respect to a change in a total angle that includes a road surface angle and a vehicle attitude angle while the vehicle is at rest, and maintains the optical axis with respect to a change in the total angle while the vehicle is traveling. The control unit fixes the optical axis angle when a fault state of the control device is detected. Upon the control device having recovered from a fault state, the control unit generates an adjustment signal either upon estimating a current vehicle attitude angle on the basis of an output value from the tilt sensor obtained while the vehicle is traveling, or upon receiving a signal indicating a current vehicle attitude angle from an external device.

To determine spatial orientation of a vehicle, a set of illuminators is mechanically coupled to the vehicle so as to emit light toward a roadway. A set of sensors is mechanically coupled to the vehicle to receive the emitted light as reflected from the roadway. A timer determines times of flight between emission of the light by the set of illuminators and reception of the reflected light by the set of sensors. A processor determines the spatial orientation of the vehicle from a difference in the times of flight.

A system and method control a vehicular headlamp for preventing a shadow area between a low beam and a high beam of a headlamp using a camera unit. The method includes periodically determining whether a high beam of the vehicular headlamp is lit or illuminated. Upon determining that the high beam is illuminated, the method includes determining whether a darkness cell is formed in front image data of the vehicle, which is transmitted from a camera unit. Upon determining that the darkness cell is formed, the method includes changing a leveling motor to be directed upward by 1 step and storing a changed number of steps. Upon determining that the darkness cell is not formed, the method includes driving the leveling motor by the pre-stored number of steps.

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 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.