A mirror reflective element sub-assembly for use in an exterior rearview mirror assembly of a vehicle includes a mirror reflective element, a mirror reflector and a mirror back plate disposed at the rear side of the mirror reflective element. A heater pad is disposed between the mirror reflective element and the mirror back plate and has a light transmitting portion that is aligned with an aperture of the mirror back plate. A blind spot indicator module includes a body portion and a connector portion extending laterally from the body portion. Light emitted by at least one light emitting diode passes through the light transmitting portion of the heater pad and through a light-transmitting portion of the mirror reflector and exits the mirror reflective element to provide a visual icon visible to a driver of the vehicle who is driving the vehicle and who is viewing said mirror reflective element.

A laminated glazed roof includes a first glazing, forming an exterior glazing, with first and second main faces; a lamination interlayer made of polymeric material of thickness e1 of at most 1.8 mm; a second glazing, forming an interior glazing, with third and fourth main faces, the second and third main faces being the internal faces of the laminated glazing; and a set of diodes that are housed in through apertures or blind holes of the lamination interlayer.

A light bar has a circuit board positioned within a housing and having a plurality of light emitting diodes (LEDs) or a thin-film-transistor liquid-crystal display (TFT LCD) is configured to transmit light. The housing has wiring electrically connected to a controller. The controller is configured to receive signals from the electrical system of the vehicle, interpret the signals received from the electrical system of the vehicle, and in response automatically control illumination of independently controllable segments of the vehicle light bar. The controller is initially programmed to perform specific function(s) and/or strobe according to specific patterns and is thereafter at least partially restricted from being reprogrammed by a user to serve other function(s), either by restricting the emission of light in at least one color and/or preventing specific strobing pattern(s).

The control part controls a timing of changing the light emission intensity of the first light source and a timing of changing the light emission intensity of the second light source such that a first light-shielding portion is formed in a part of the first irradiation pattern, a second light-shielding portion is formed in a part of the second irradiation pattern so as to overlap with the first light-shielding portion, and a range of the first light-shielding portion and a range of the second light-shielding portion are deviated from each other.

A light bar has a circuit board positioned within a housing and having a plurality of light emitting diodes (LEDs) or a thin-film-transistor liquid-crystal display (TFT LCD) is configured to transmit light. The housing has wiring electrically connected to a controller. The controller is configured to receive signals from the electrical system of the vehicle, interpret the signals received from the electrical system of the vehicle, and in response automatically control illumination of independently controllable segments of the vehicle light bar. The controller is initially programmed to perform specific function(s) and/or strobe according to specific patterns and is thereafter at least partially restricted from being reprogrammed by a user to serve other function(s), either by restricting the emission of light in at least one color and/or preventing specific strobing pattern(s).

A lever switch includes a lever main body and a rotary operation element rotatably provided at a tip end portion of the lever main body. The rotary operation element is provided with a light ON switch position at which an instruction to cause head lights and small lights to be on at all times is issued, an automatic light switch position at which an instruction to set an automatic light mode, in which a turned-on state of the head lights and the small lights is controlled based on the intensity of illumination in the vicinity of the vehicle, is issued, and a light OFF switch position at which an instruction to turn the head lights off is issued, the light ON switch position, the automatic light switch position, and the light OFF switch position being arranged in an order along a rotation direction.

A lighting system for a vehicle and a corresponding motor vehicle is implemented with personalized or individualizable lighting functions. A part of a lighting device is reserved for implementing main lighting functions in accordance with legal requirements and another part of the lighting device is reserved for generating individualizable lighting functions. The part for individualizable lighting functions can be freely programmed and actuated via a user interface, such as a smartphone, within the scope of the technical power limitations of the individual lighting devices while taking into consideration legal requirements.

A covering device for fully or partially covering one or more of a recess, a flat portion, a curved portion, and a stepped portion of at least one of a vehicle body component and a vehicle part includes a cover element provided by a strip element or a cap element, and at least one lip element which is fixedly or detachably connected to the cover element on at least one of its longitudinal sides, the covering device is designed so that light from a lighting device can shine through at least a portion of the covering device, at least one of the cover element and the at least one lip element is made at least partly of a polymeric substrate which is coated with a chromium-based reflective coating material, and the polymeric substrate and the chromium-based reflective coating are at least partially translucent.

An auxiliary vehicle lighting system is provided for use in a vehicle having an engine and an electrical system. The auxiliary vehicle lighting system has at least one auxiliary vehicle light; a control hub, connected to the vehicle electrical system and to each auxiliary vehicle light; and a system shut down function or program, connected to the control hub and configured to de-energize the auxiliary lighting system. The control hub is constructed and arranged so that upon illumination of the auxiliary vehicle lights and with the engine turned off, the vehicle battery voltage is monitored. If the battery voltage reaches a designated low voltage target, the system shut down function or program is activated, which de-energizes the auxiliary lights.

A light bar has a circuit board positioned within a housing and having a plurality of light emitting diodes (LEDs) or a thin-film-transistor liquid-crystal display (TFT LCD) is configured to transmit light. The housing has wiring electrically connected to a controller. The controller is configured to receive signals from the electrical system of the vehicle, interpret the signals received from the electrical system of the vehicle, and in response automatically control illumination of independently controllable segments of the vehicle light bar. The controller is initially programmed to perform specific function(s) and/or strobe according to specific patterns and is thereafter at least partially restricted from being reprogrammed by a user to serve other function(s), either by restricting the emission of light in at least one color and/or preventing specific strobing pattern(s).