The present invention may include a replaceable vehicle light including a lamp body, a printed circuit board (pcb) supported by the lamp body, and the pcb may include a plurality of individual lights arranged in a radial pattern. A controller chip may be included on the pcb, the controller chip may provide electrical energy to each of the individual lights, thereby enabling selective illumination of each of the individual lights. The controller chip may provide a lighting designation, wherein some of the individual lights are designated as primary lights being illuminated at a first brightness, which may illuminate in a radial pattern. The radial pattern may provide a more visible pattern which may be more distinguishable from other roadway lighting, thereby increasing visibility of the replaceable vehicle light.

A control system for a vehicle display, such as a CHMSL, includes a control system module having an OEM connector first portion pre-attached to input wires and OEM connector second portion pre-attached to output wires. In another example, a control system for a vehicle display includes a control system module having a control system module input adaptor for removably connecting the control system module to an OEM first connector portion and a control system module output adaptor for removably connecting the control system module to an OEM second connector portion. Control systems for a vehicle display can be inserted between an input system and a vehicle display without having to identify specific wire harnesses or wires, and without cutting any wires. Different adaptors can be used to insert a single disclosed control system between an input system and a vehicle display in multiple types and makes of vehicles.

Dimmable external vehicle lighting and methods of use are provided herein. An example method includes determining environmental light intensity around a vehicle, determining a luminance of an external light of the vehicle, determining a difference in magnitude between the environmental light intensity and the luminance of the external light, and selectively adjusting the luminance of the external light based on the difference.

The invention relates to a signalling device (1) designed to be removably placed on the back of a user of a locomotive engine, the device (1) including electronic means for signal processing and for controlling the switching-on and/or switching-off of the at least one secondary signal light (3d, 3g) synchronously with the switching-on and/or switching-off of a primary signal light present in the machine. Electronic means are built into an accelerometer and means for interpreting measurements of the accelerometer allow the detection of a lateral variation, to the right or left, of the direction of movement, the means for controlling the at least one secondary signal light (3d, 3g) comprising means for verifying that the at least one secondary signal light (3d, 3g) indicates the lateral right or left direction followed by the user and the machine.

An automotive light comprising a lighting assembly which is located inside the rear body, is adapted to backlight a corresponding transparent or semi-transparent sector of the front half-shell, and comprises: a pair of light-guide bars made of photoconductive material, which extend toward each other inside the rear body, while remaining both substantially grazing the front half-shell, and have their respective proximal ends adjacent and aligned to one another; and a pair of electrically-powered light sources that are located within the rear body each adjacent to the distal end of a respective light-guide bar, and are oriented so as to direct the light produced inside the body of the facing light-guide bar; the proximal ends of both light-guide bars being shaped so as to form respective plate-like heads that are locally substantially coplanar to each other and are arranged inside the rear body one spaced beside the other, so as to form/delimit therebetween a small transversal slot, which is substantially straight and is inclined with respect to the local longitudinal axis of the same light-guide bars.

A digital license plate includes a display system capable of showing a license number readable by camera systems even under poor external lighting conditions. A light redistribution element is positioned near the display system and a lighting system is positioned to direct light from the light redistribution element and toward the display system. In some embodiments the lighting system includes a non-visible lighting element such as can be provided by an infrared source, and the display system includes an electrophoretic or LCD display.

A method of activating a vehicle function is provided. The method includes detecting a force exerted onto a bed step of a vehicle using a pressure sensor. A controller detects whether the amount of force exerted onto the bed step is greater than a force threshold. When the force exertion force exceeds the force threshold, one of a plurality of pressure patterns is detected. One of a plurality of vehicle functions is then activated based on the detected pressure pattern.

A method for controlling intensity of at least one headlamp and/or at least one brake lamp of a vehicle, characterized by the step of reducing intensity of the at least one headlamp and/or brake lamp when direction indicators are activated.

Devices, systems, and methods for management of electrical resources for electric vehicles. A method may include receiving, by a vehicle, sensor data indicative of a first luminosity of a location, and determining that the first luminosity of the location exceeds a luminosity threshold. The method may include determining, based on the first luminosity exceeding the luminosity threshold, a second luminosity to apply to lights of the vehicle while the vehicle is at the location, the second luminosity greater than zero. The method may include applying the second luminosity to the lights while the vehicle is at the location.

Automatic drive mode lighting systems and methods are disclosed herein. An example method can include determining when a drive mode of a vehicle is an off-road mode, determining when a speed of the vehicle is below a speed threshold, determining when a location of the vehicle corresponds to an off-road location, and automatically activating off-road lighting for the vehicle when the drive mode is in an off-road mode, the speed is below the speed threshold, and the location corresponds to an off-road location.