A vehicle display device mounted on a vehicle and configured to display an image to an outside of the vehicle includes: a self-luminous display unit configured to display an image to the outside of the vehicle by emitting light emitted from a light source to the outside of the vehicle; a reflective display unit configured to display an image to the outside of the vehicle by reflecting light from the outside of the vehicle; an information acquisition unit configured to acquire environment information indicating an environment outside the vehicle; and a controller configured to switch between image display by the self-luminous display unit and image display by the reflective display unit based on the acquired environment information.

The invention relates to a method, performed by a control device (10), for controlling a vehicle lighting device (100), the vehicle lighting device (100) includes the control device (10); and at least one electronic display unit (20) arranged at one end (12, 14) of a vehicle (1), wherein the control device (10) is arranged to control the at least one display unit (20) to show various types of vehicle lights (22). The method includes: collecting (s101) data relating to the vehicle surroundings; and controlling (s102) the at least one display unit (20) to adapt at least one vehicle light (22) based on the collected data.

An illuminable vehicle component and a method for illuminating a vehicle component includes a vehicle component including an A-surface, a photoluminescent or electroluminescent light source covering the A-surface, a pigmented layer coving the photoluminescent or electroluminescent light source, and an optional optically clear top coat covering the pigmented layer. When the photoluminescent or electroluminescent light source is not activated and is not emitting light, the pigmented layer has an opaque appearance. When the photoluminescent or electroluminescent light source is activated to emit light, light emitted from the photoluminescent or electroluminescent light source is transmitted through the pigmented layer and the optional optically clear top coat such that the illuminable vehicle component has an illuminated appearance and the component is illuminated.

A display device of a vehicle includes: a display provided inside of the vehicle; an interior lighting device lighting up an inside surface of a passenger compartment of the vehicle at an outside of the display; and a control device controlling the display and the interior lighting device. The control device is configured so that when a condition for moving display stands, the display is made to show a moving display element moving toward an outer circumference of the display, and so that when the moving display element reaches the outer circumference of the display, the interior lighting device lights up an inside surface of a passenger compartment of the vehicle so that a light part lit by the interior lighting device appears to move successively from the moving display element.

A vehicle includes a storage compartment configured to house a package for delivery and a side-mirror assembly. The side-mirror assembly includes an imager and a puddle light aimed to illuminate an area in a field of view of the imager. A vehicle controller is programmed to receive data representing a code associated with the delivery, energize the puddle lamp to illuminate the area, and unlock the storage compartment responsive to the imager detecting an image encoding data matching the code.

The present disclosure relates generally to safety lighting devices for automotive vehicles. A safety lighting system coupled to an automotive vehicle includes a power source that is independent of an electrical system of the vehicle. The system also includes a lighting feature electrically coupled to the power source, wherein the lighting feature is configured to activate in response to an impact event.

A lighting assembly for a vehicle includes a polymeric layer and a first conductive layer coupled to the polymeric layer. A first metallic foil defined a plurality of first foil apertures. A semiconductor layer includes a plurality of perovskites. A second conductive layer is coupled to the semiconductor layer. A second metallic foil defines a plurality of second foil apertures. The lighting assembly includes transparent overmold, extending through the plurality of first foil apertures, the first and second conductive layers, the semiconductor layer, and the plurality of second foil apertures to contact the polymeric layer.

A painted vehicle trim component such as a spoiler, side-view mirror housing, or other vehicle body part is provided with electroluminescent paint to emit light from its surface. The trim component includes a substrate having a mounting surface for attaching to the vehicle. A conductor body is at least partially embedded in the substrate to provide a conductive surface exposed externally of the substrate. A conductive wire is crimped to the conductor body and is adapted to connect to an electrical power source remotely from the vehicle trim component. A conductive bus bar paint layer is deposited over the substrate and onto the exposed conductive surface of the conductor body. A light-emitting paint layer deposited over the substrate is disposed relative to the conductive paint layer such that light is emitted when an electrical signal is received at the conductive wire.

Methods, systems and apparatuses are disclosed for incorporating an illumination assembly comprising a plurality of micro-light sources into an exterior surface of a vehicle for the purpose of producing predetermined fixed or sequenced visual images.

An illuminatable vehicle assembly according to an exemplary aspect of the present disclosure includes, among other things, a dielectric layer that emits light. The dielectric layer is disposed between an anode layer and a cathode layer. The assembly further includes a color conversion layer that converts light emitted from the dielectric layer.