A method for visualizing sensor data from the surroundings of a vehicle and/or measuring data from the vehicle uses light modules in the interior of the vehicle for the visualization of the sensor data. The sensor data is detected as video data, after which the video data is analyzed in relation to relevant recognizable structures, after which the relevant structures are transferred to a video sequence with a format fitting for the respective light module, and/or sensor data not detected as video data and/or measuring data is recalculated into video sequences via an algorithm, after which the video sequences from the different data are superimposed and displayed on the light modules.

A method for visualizing sensor data from the surroundings of a vehicle and/or measuring data from the vehicle uses light modules in the interior of the vehicle for the visualization of the sensor data. The sensor data is detected as video data, after which the video data is analyzed in relation to relevant recognizable structures, after which the relevant structures are transferred to a video sequence with a format fitting for the respective light module, and/or sensor data not detected as video data and/or measuring data is recalculated into video sequences via an algorithm, after which the video sequences from the different data are superimposed and displayed on the light modules.

A mood lamp with dynamic effect and a vehicle provided with the mood lamp may include a bracket mounted on a vehicle body; a cover provided on the bracket and used to form an appearance of the mood lamp; a light guide plate provided in an accommodation space formed by the cover and the bracket, adjacent to the cover, and including a surface close to the cover and including an uneven wave pattern, wherein a metal plating layer is provided on the surface including the wave pattern; a light source provided in the accommodation space to be close to one side of the light guide plate and far away from the other side of the light guide plate; and a light reflection film provided in the accommodation space and reflecting a light emitted by the light source to a surface of the light guide plate far away from the cover.

A mood lamp with dynamic effect and a vehicle provided with the mood lamp may include a bracket mounted on a vehicle body; a cover provided on the bracket and used to form an appearance of the mood lamp; a light guide plate provided in an accommodation space formed by the cover and the bracket, adjacent to the cover, and including a surface close to the cover and including an uneven wave pattern, wherein a metal plating layer is provided on the surface including the wave pattern; a light source provided in the accommodation space to be close to one side of the light guide plate and far away from the other side of the light guide plate; and a light reflection film provided in the accommodation space and reflecting a light emitted by the light source to a surface of the light guide plate far away from the cover.

A mood lamp with dynamic effect and a vehicle provided with the mood lamp may include a bracket mounted on a vehicle body; a cover provided on the bracket and used to form an appearance of the mood lamp; a light guide plate provided in an accommodation space formed by the cover and the bracket, adjacent to the cover, and including a surface close to the cover and including an uneven wave pattern, wherein a metal plating layer is provided on the surface including the wave pattern; a light source provided in the accommodation space to be close to one side of the light guide plate and far away from the other side of the light guide plate; and a light reflection film provided in the accommodation space and reflecting a light emitted by the light source to a surface of the light guide plate far away from the cover.

It is intended to cause a light emitter to properly emit light for notifying an occupant of a movement direction of an object approaching a conveyance. A vehicle lighting device includes sensors (3a, 3b, 3c, 3d) configured to detect an approaching object approaching a vehicle, light emitters (5) attached to the vehicle, and a control device (2) configured to control the light emitter (5) when the sensor (3a, 3b, 3c, 3d) has detected the approaching object. The control device (2) controls the light emitter (5) such that a light emitting spot of the light emitter (5) moves along a direction corresponding to a movement direction of the approaching object.

It is intended to cause a light emitter to properly emit light for notifying an occupant of a movement direction of an object approaching a conveyance. A vehicle lighting device includes sensors (3a, 3b, 3c, 3d) configured to detect an approaching object approaching a vehicle, light emitters (5) attached to the vehicle, and a control device (2) configured to control the light emitter (5) when the sensor (3a, 3b, 3c, 3d) has detected the approaching object. The control device (2) controls the light emitter (5) such that a light emitting spot of the light emitter (5) moves along a direction corresponding to a movement direction of the approaching object.

A method for visualizing sensor data from the surroundings of a vehicle and/or measuring data from the vehicle uses light modules in the interior of the vehicle for the visualization of the sensor data. The sensor data is detected as video data, after which the video data is analyzed in relation to relevant recognizable structures, after which the relevant structures are transferred to a video sequence with a format fitting for the respective light module, and/or sensor data not detected as video data and/or measuring data is recalculated into video sequences via an algorithm, after which the video sequences from the different data are superimposed and displayed on the light modules.

A method for visualizing sensor data from the surroundings of a vehicle and/or measuring data from the vehicle uses light modules in the interior of the vehicle for the visualization of the sensor data. The sensor data is detected as video data, after which the video data is analyzed in relation to relevant recognizable structures, after which the relevant structures are transferred to a video sequence with a format fitting for the respective light module, and/or sensor data not detected as video data and/or measuring data is recalculated into video sequences via an algorithm, after which the video sequences from the different data are superimposed and displayed on the light modules.

An apparatus and system are disclosed and include a vehicle interior lighting system comprising that includes a light engine with a plurality of independently addressable light emitting diode (LED) segments, each independently addressable LED segment including at least one LED, a flexible printed circuit board (PCB) having a base and plurality of legs extending from the base, each leg supporting an independently addressable LED segment, and a light guide plate configured to provide illumination from the plurality of independently addressable LED segments inside the vehicle. A processor may be configured to receive information from a o vehicle sensing system, a vehicle communication system, or a detection system, and may generate a signal. A controller may be configured to provide one or more light control signals to modify at least one light characteristic of at least one of the plurality of independently addressable LED segments based on the signal.