A vehicle control system includes a camera configured to capture image data depicting a field of view proximate the vehicle is disclosed. The vehicle control system further includes a plurality of light sources in connection with the vehicle and a controller. The controller is configured to activate a plurality of lights in an alternating pattern and capture light reflected from at least one object with the camera at a time and corresponding to the alternating pattern of the plurality of lights. In response to variations in the light impinging upon the at least one object from the alternating pattern, the controller is configured to identify a distance of the object.

A method, system and non-transitory computer readable medium for suppressing autonomous vehicle external human machine interface (eHMI) notifications to prevent confusion or distraction of a road user. The suppression conditions are based on situations where the eHMI notification is redundant, not necessary, can be simplified or should be modified due to weather or light intensity. The eHMI notifications can be suppressed on selected displays and enhanced on others. The eHMI notifications can include text and icons, flashing lights, color or light patterns, which can be modified or suppressed based on the determination that the eHMI notification will confuse or distract the road user. At a four-way stop intersection, the eHMI notification can be suppressed until the autonomous vehicle has the right-of-way. The autonomous vehicle can form a mesh network with connected vehicles at the intersection and broadcast a group eHMI while requesting that the connected vehicles suppress their eHMIs.

An image capture apparatus includes a light source, a modulator configured to modulate light irradiated from the light source to a target object, an imaging device configured to generate image data by capturing one or more images of the target object, and processing circuitry. The processing circuitry is configured to drive the modulator by a first modulation signal, the first modulation signal being for irradiating a first pattern, drive the modulator by a second modulation signal, the second signal being for irradiating a second pattern, wherein the first pattern and the second pattern are irradiated alternately, modulate reflected light from the target object, the reflected light from the target object being detected at a lock-in detector, and generate an image composed of image data from the reflected light of the plurality of localized illuminations.

An image capture apparatus includes a light source, a modulator configured to modulate light irradiated from the light source to a target object, an imaging device configured to generate image data by capturing one or more images of the target object, and processing circuitry. The processing circuitry is configured to drive the modulator by a first modulation signal, the first modulation signal being for irradiating a first pattern, drive the modulator by a second modulation signal, the second signal being for irradiating a second pattern, wherein the first pattern and the second pattern are irradiated alternately, modulate reflected light from the target object, the reflected light from the target object being detected at a lock-in detector, and generate an image composed of image data from the reflected light of the plurality of localized illuminations.

A multi-light control module assembly for controlling multiple lamps on a motorized vehicle includes a circuit board module having a first end, a second end, a first side, and a second side. The board has a length defined between the first end and the second end and a width defined between the first side and the second side. A diode assembly is coupled to the module towards the second end thereof, and a connector assembly is coupled to the module adjacent to the diode assembly. The connector assembly is electrically coupled to the diode assembly. A first channel is defined between a first arm and a main portion of the module, and a second channel defined between a second arm and the main portion of the module. A cap is removably coupled to the connector assembly configured for partially housing a pair of wires receiving in the connector assembly.

A lamp system for traffic lane indication using a navigation link may include a multi-function sensor sensing an environment and a line in front of a host vehicle, a line lamp generating and outputting a prediction line at a location corresponding to a line of a road, a navigation device providing location information of the host vehicle, and a vehicle controller predicting a forward line based on a line sensed by the multi-function sensor, and the location information of the host vehicle provided by the navigation device and controlling the line lamp to output the prediction line to follow the predicted forward line.

A lamp system for traffic lane indication using a navigation link may include a multi-function sensor sensing an environment and a line in front of a host vehicle, a line lamp generating and outputting a prediction line at a location corresponding to a line of a road, a navigation device providing location information of the host vehicle, and a vehicle controller predicting a forward line based on a line sensed by the multi-function sensor, and the location information of the host vehicle provided by the navigation device and controlling the line lamp to output the prediction line to follow the predicted forward line.

Vehicle bumper assembly including a bumper body, a pair of lamp modules and one or more controllers. The bumper body is configured to be arranged at least partially across one of a front and rear end of the vehicle (not illustrated). The body defines opposed sides. The pair of lamp modules are mounted to the bumper body to be spaced from each other and towards one of the sides. Each lamp module includes one or more light emitting units arranged to extend at least partially across the lamp module. The, or each, controller is configured to operate one or both of the lamp modules to cause the one or more light emitting units to sequentially illuminate to indicate a turn direction of the vehicle.

Vehicle bumper assembly including a bumper body, a pair of lamp modules and one or more controllers. The bumper body is configured to be arranged at least partially across one of a front and rear end of the vehicle (not illustrated). The body defines opposed sides. The pair of lamp modules are mounted to the bumper body to be spaced from each other and towards one of the sides. Each lamp module includes one or more light emitting units arranged to extend at least partially across the lamp module. The, or each, controller is configured to operate one or both of the lamp modules to cause the one or more light emitting units to sequentially illuminate to indicate a turn direction of the vehicle.

The present invention relates to a motor vehicle light device that includes an optical deflector, at least one bearing element, and a pinning element. The pinning element has a bracing element bearing a contact portion, the bracing element at least partially surrounding the optical deflector, the contact portion bearing against the optical deflector. The optical deflector, the bearing element and the pinning element are arranged so that the optical deflector is at least partially gripped between the bearing piece and the contact portion, so that, in a direction running from the bearing piece to the contact portion, the contact portion is rigid and the bracing element is elastically deformable.