A method comprising: (a) heating a light module of a vehicle with a heater; (b) monitoring a temperature of the light module; (c) activating a communication sequence; and (d) performing the communication sequence so that a message is conveyed between a controller of the light module and a controller of the vehicle.

A vehicle and a controlling method of the same include a speaker outputting virtual engine sound integrated with a head lamp. The vehicle includes the head lamp; a head lamp case in which the head lamp is provided; and a speaker for outputting a virtual engine sound, and provided inside the head lamp case, where an internal cross-sectional area of the head lamp case may increase in a direction toward a front of the vehicle based on a position where the speaker is provided.

A LiDAR-integrated lamp device for a vehicle, wherein a headlamp and a LiDAR system are mounted at the same position, such that the layout may be reduced and the number of parts may be decreased by sharing and combining parts, reducing the manufacturing cost.

An illumination and detection lamp assembly (100) and a vehicle. The illumination and detection lamp assembly (100) comprises: a lamp assembly body (110); an illumination light source (121), disposed in the lamp assembly body (110), and used for emitting illumination light to the outside; and a detection signal source, disposed in the lamp assembly body (110), and used for sending a detection signal to the outside to detect the position of an object around the lamp assembly body (110).

The invention proposes a lighting device for a motor vehicle comprising a matrix light source that performs a lighting function within the motor vehicle. The same source is used, together with a photodiode, to estimate the time of flight of captured light pulses initially generated by the matrix source. It becomes possible to detect objects and/or gestures using light in the visible spectrum, and without having to use specific pulse sources dedicated for this purpose.

An aircraft navigation light includes: a navigation lighting arrangement, having: a power input, couple able to an aircraft on-board power supply network, at least one navigation light source, and a power conditioning circuit, coupled between the power input and the at least one navigation light source for conditioning a power flow from the power input to the at least one navigation light source; an auxiliary power supply, coupled to the power conditioning circuit for diverting power from the navigation lighting arrangement; and a power supply output, coupled to the auxiliary power supply, for supplying power from the auxiliary power supply to an exterior aircraft light, external to the aircraft navigation light.

A vehicular control system includes a plurality of sensors that include at least a camera and a 3D point-cloud LIDAR. As the vehicle travels along a road, and responsive at least in part to processing at an electronic control unit of 3D point-cloud LIDAR data captured by the 3D point-cloud LIDAR, the vehicular control system (a) determines presence of a pedestrian or cross traffic vehicle present exterior of the vehicle that (i) is not on the road that is being travelled along by the vehicle and is approaching the road to cross the road ahead of the vehicle and (ii) is at least in the field of sensing of the 3D point-cloud LIDAR and (b) at least in part controls at least one vehicle function of the vehicle responsive at least in part to the determined presence of the pedestrian or cross traffic vehicle.

A sensor system includes a first sensor, a second sensor, a cover, and a control device. The first sensor detects, with first light, a state of a first area located outside a vehicle and outputs first detecting information corresponding to the state. The second sensor detects, with second light, a state of a second area located outside the vehicle and at least partially overlapping with the first area, and outputs second detecting information corresponding to the state. The cover covers at least one of the first and second sensors while forming a part of an outer face of the vehicle and allows passage of at least one of the first and second light. The control device detects an abnormality of the cover based on an inconsistency between the first and second detecting information that are outputted for an area where the first area and the second area overlap.

A computer includes a processor and a memory storing instructions executable by the processor to receive radar data from a radar sensor of a vehicle; demarcate a zone of coverage of the radar sensor, the zone of coverage having an area based on a number of objects indicated by the radar data; and after demarcating the zone of coverage, in response to detecting a newly present object in the zone of coverage, adjust a scanning rate of the radar sensor based on a distance of the newly present object from the radar sensor.

A vehicle lamp includes a light source, a lighting control unit configured to control an emission timing of light emitted from the light source, and a rotary scanning unit configured to repeatedly perform scanning with the light emitted from the light source while rotating. The vehicle lamp illuminates a predetermined region with scan light. The rotary scanning unit performs plural repetitive scans in one rotation. The lighting control unit detects a rotation cycle of the rotary scanning unit, and controls the emission timing of the light source at a timing obtained by equally dividing the detected rotation cycle.