An illumination device is provided for vehicles, the illumination device including a matrix assembly containing a number of lighting elements arranged in the form of a matrix, each of which can be actuated individually and independently of each other. A line assembly is provided for with a number of light sources and a lens unit for generating a linear signal light function. The matrix assembly is at least partially a component of the line assembly. One part of the matrix assembly forms one part of the linear assembly.

A lamp for a vehicle or other object that includes multiple functions. In one aspect, the lamp includes a first circuit for emitting a first color light (such as red light), and at least a second circuit for emitting a second color of light (such as amber light). In another aspect, the lamp optionally includes a microcontroller that may be programmed to control the activation of the different colored lamp circuits based on lamp location information, and based on an operating mode.

An electric scooter with a lighting system that includes a rear mounted light that projects light upward and toward the front of the scooter to illuminate the back of a rider, and side lights that project light to illuminate the sides of a scooter. The lighting system employs a multi-faceted approach to vary intensity and effects for improved visibility in traffic. The light system can be configured to automatically illuminate or change effects in response to road or environmental conditions, or in response to existing or future roadway infrastructure such as autonomous traffic infrastructure or adaptive traffic control systems. The light system may also be integrated with the braking system for signaling a slow down or stop. The system may be controlled by communication between an onboard processor and a personal computing device such as a smart phone that can be docked on the scooter and provide display of information and a means of input.

An electric scooter with a lighting system that includes a rear mounted light that projects light upward and toward the front of the scooter to illuminate the back of a rider, and side lights that project light to illuminate the sides of a scooter. The lighting system employs a multi-faceted approach to vary intensity and effects for improved visibility in traffic. The light system can be configured to automatically illuminate or change effects in response to road or environmental conditions, or in response to existing or future roadway infrastructure such as autonomous traffic infrastructure or adaptive traffic control systems. The light system may also be integrated with the braking system for signaling a slow down or stop. The system may be controlled by communication between an onboard processor and a personal computing device such as a smart phone that can be docked on the scooter and provide display of information and a means of input.

The present invention relates to a through-type taillight and a vehicle having same. Specifically, the through-type taillight is installed in an accommodation of a vehicle tail component, and has an outer lens, a housing and a side part, the housing being closed by the outer lens, and together with the outer lens defining an accommodating space for accommodating an optoelectronic component of the through-type taillight, wherein the side part is arranged on a side of the housing in such a way as to prevent loosening, and at least occupies a first position and a second position relative to the housing, such that in the first position the through-type taillight can be fitted into the accommodation, and in the second position the side part forms a corresponding compensating face of the vehicle tail component.

A priority control circuit for the operation of vehicle lamps. The priority control circuit includes a first circuit and a second circuit. The first circuit includes a first PNP transistor, a first NPN transistor having a gate connected to a collector of the first PNP transistor, and a first output port connected to a collector of the first NPN transistor. When a first lamp turn-on signal for turning on a first lamp is input, the first circuit turns on a second lamp and a third lamp. The second circuit includes a second NPN transistor, a second PNP transistor having a gate connected to a collector of the second NPN transistor, and a second output port connected to a collector of the second PNP transistor. The second circuit controls priorities for the operation of the second lamp and the third lamp.

A mounting bracket for attaching an electrical coupling of trailer light electrical system to the hitch receiver tube of a towing vehicle is described. The mounting bracket removably attaches to the receiver tube such that the bracket does not interfere with the tube opening and has a electrical coupling mount flange that is located sideways from the receiver tube in a cantilever like fashion.

A safety lighting system for use with trailers is described herein. In some embodiments, the trailer lighting system comprises a sensor, a controller, and safety lights. The safety lighting system may be used for illuminating trailers while being towed, for example, in shipping yards, construction yards, and shipping and receiving docks. The safety lighting system may be activated upon connection of a pneumatic system with a spotting tractor and deactivated upon establishing an electrical connection from a tractor to the trailer.

A lighted applique for a vehicle body panel including an opaque body panel applique and one or more display element cutouts each having a cutout profile formed in the opaque body panel applique. At least one non-opaque display element is mounted within the one or more display element cutouts such that a panel engagement surface is in contact with a panel exterior surface. At least one LED strip is mounted within the at least one LED strip channel and an electrical connection assembly is in communication with the at least one LED strip.

A lighted applique for a vehicle body panel including an opaque body panel applique and one or more display element cutouts each having a cutout profile formed in the opaque body panel applique. At least one non-opaque display element is mounted within the one or more display element cutouts such that a panel engagement surface is in contact with a panel exterior surface. At least one LED strip is mounted within the at least one LED strip channel and an electrical connection assembly is in communication with the at least one LED strip.