A system for implementing strobing of existing vehicle hazard lights including an interface to a vehicle wiring harness configured to receive input to an existing vehicle flasher module, and a strobing circuit that responds to an activation signal from the vehicle wiring harness that is indicative of a hazard flasher deployment event by producing an electrical output through the interface to the vehicle wiring harness that causes a strobing of existing vehicle hazard lamps.

A vehicle LED lighting outage detection circuit is disclosed for detecting a fault in the LED light and automatically increasing the power drawn from the light power supply in response to the fault. A complementary detection circuit is also disclosed for detecting the increased power draw and signaling a fault to an operator. The increased power draw can be selected to be in the form of a pulse that settles to a lower power draw state after a time to avoid excessive and wasteful power draw. The system can be mounted in a vehicle and, more particularly, to a semi- tractor truck.

A coupling control module according to the invention, comprises the coupling control module designed to transmit at least one configuration bus message to the at least one motor vehicle bus module via the bus interface, wherein the configuration bus message contains a configuration identifier to be entered in configuration data of the motor vehicle bus module, wherein the configuration identifier is provided so that when the motor vehicle continues to be operated, at least one motor vehicle bus module can execute at least one function according to the existence of the trailer coupling and/or according to bus messages received from the coupling control module on the basis of received configuration identifier.

A rearview safety warning device of a vehicle has a rearview mirror assembly, a display unit, a wireless transmission unit, and a processing unit. The rearview mirror assembly has a mirror having a mirror-surface area and a display area. The display unit displays a warning information through the display area of the mirror. The wireless transmission unit communicates with a mobile device via a wireless communication technique. The processing unit is signally connected to the display unit and the wireless transmission unit. The processing unit receives a traffic data from the mobile device via the wireless transmission unit and activates the display unit to display the warning information according to the traffic data.

An apparatus for defrosting a vehicle light comprises a frame, a heating element connected to at least a portion of an internal facing surface of the frame, an attachment mechanism, and an electrical communication connection electrically connected between the heating element and a power source. The heating element may be configured to generate heat in the direction of the vehicle light, thereby melting snow, ice, or frost buildup on or in the vehicle light.

The present invention relates to a vehicle U-turn indicator system to alert other motorists, cyclists and pedestrians of a potential U-turn made by a vehicle. The indicator is an inverted “U” shaped device having LED lights configured to blink in a running manner from one end to other and vice versa. The blinking of LED lights in one direction indicates U-turn of the vehicle in one direction (i.e. left) and in another direction indicates a U-turn of the vehicle in another direction (i.e. right). The indicator can be mounted to the front and rear of the vehicle in addition to side mirrors. An actuator is used for activating the U-turn indicator in a preferred direction.

A system includes one or more upfitter switches and a plurality of controllable vehicle features, wherein at least two of the features are controllable by a first of the upfitter switches, based on a dynamic configuration of the first upfitter switch. The system also includes a processor that can determine that a trigger state for reconfiguring the first upfitter switch has occurred and re-assign the first upfitter switch from controlling a first of the at least two features to controlling a second of the at least two features, responsive to the trigger state.

A vehicle lighting system for use on a motor vehicle having an auxiliary device assembled on the motor vehicle is provided. The vehicle lighting system includes a first lighting system located on a body of the vehicle. The first lighting system has a plurality of different lights. A second lighting system is located on the auxiliary device. The second lighting system has a plurality of different lights. A control circuit operates one or more of the plurality of different lights in the second lighting system based on an operating sequence of one or more of the plurality of different lights in the first lighting system.

A system for implementing strobing of existing vehicle hazard lights including an interface to a vehicle wiring harness configured to receive input to an existing vehicle flasher module, and a strobing circuit that responds to an activation signal from the vehicle wiring harness that is indicative of a hazard flasher deployment event by producing an electrical output through the interface to the vehicle wiring harness that causes a strobing of existing vehicle hazard lamps.

A retrofittable modular school bus safety apparatus comprising a CPU, a plurality of sensors and scanners, an electrical plug device, and an output device. The electrical plug device is preferably adapted to plug into an auxiliary power port, a USB port or an OBD port to provide electrical power to the apparatus and to provide actuatable communication to school bus devices such as lights, horns, crossing arm, etc. The sensors include machine vision sensors, proximity detection sensors, and speed detection sensors. The apparatus is adapted to “read” a vehicle's license plate via ALPR, perform facial recognition, automatically monitor and warn/alert traffic proximate the school bus, to automatically respond with an appropriate level of response depending on an observed level of a moving violation, and to automatically wirelessly obtain the traffic laws/regulations applicable to location of the school bus and to operate accordingly.