A light assembly and method for installing the same on a surface in a wet or outdoor environment, e.g., on a marine vessel or land recreational or other vehicle, such as marine light assemblies, without need for specialized tools or mounting assemblies. The light assembly comprises a flexible diffusion housing having a first portion and a second portion, with a groove therebetween. A light element is disposed within the interior of the first portion, and light produced by the light element is diffused by the first and second portions prior to emission outwardly from the second portion. After installation, only the second portion of the light assembly is visible on the marine vessel or land recreational surface.

The present invention relates generally to the field of vehicle lights. More specifically, the present invention relates to a multipurpose vehicle light that can be removably attached to an external surface of a vehicle or vessel. The device is solar or battery powered, does not rely on the vehicle's power source to operate, and can be removably attached to a vehicle exterior without damaging or permanently modifying the exterior. The device is further comprised of a USB port and a charging case to recharge the device, a light source comprised of a plurality of LEDs that may be remote controlled or automatically activated, a camera and a speaker.

The present invention provides a method of installing a hood scoop to a designated recessed area of a hood of a Jeep® Wrangler Rubicon vehicle comprising: providing the hood scoop having a protective member and a hood attachment member having a first cable access feature wherein: edge profile of the hood attachment member matches edge profile of the designated recessed area; the designated recessed area includes a hood aperture that provides access to the vehicle's electrical power and control systems; attaching the attachment member to the designated recessed area using conventional attachment means; and attaching a light fixture to the hood scoop wherein the light fixture's cables pass through the first cable access feature and the hood aperture for communication with the vehicle's electrical power and control systems. The present invention also provides the hood scoop described herein.

A vehicle light optical element (VLOE) comprises a light incident portion, a transmission portion, and a light emitting portion sequentially arranged from back to front. The light incident portion comprises an illuminating light incident structure (ILIS) and at least one high-beam light incident structure (HBLIS), in which an illuminating light incident surface of the ILIS is adapted to receive auxiliary light during low-beam lighting. Alternatively, the light incident portion comprises an ILIS and at least one HBLIS, in which the ILIS is either a flat surface, a curved cylindrical body protruding backwards, a hemispherical body protruding backwards, or a light condensing structure. The ILIS is adapted to receive auxiliary lighting light during low-beam lighting. The ILIS is provided on the VLOE, such that when a vehicle light is in a low-beam lighting mode, the VLOE is also luminous, thereby improving the aesthetic appearance of the vehicle light.

A vehicle lighting fixture and system where the fixture includes light emitting diodes (LEDs) and a lens. A controller monitors vehicle conditions and sends lighting commands to activate one or more LEDs based on the vehicle conditions. The LEDs can be red-green-blue (RGB) LEDs capable of emitting various different colors. The lighting commands can include illumination color, intensity level and on/off. The LEDs can be arranged in groups, where each group is separated from the other groups. The lighting commands can include a blink/steady designation, where blink causes the group to blink in the illumination color, and steady causes the group to steadily light in the illumination color. A blink frequency can control the blink rate in the illumination color. The lighting commands can include an intensity level; where when a group is activated it is illuminated in the illumination color at the intensity level.

Provided is a lamp for a vehicle capable of forming a plurality of different beam patterns. The vehicle lamp includes a light source system, a lens system, and a shield system. The lens system includes a plurality of incident lenses onto which light emitted from the light source system is incident and a plurality of exit lenses to output the light incident thereto from the plurality of incident lenses to form a predetermined beam pattern. The shield system includes a plurality of main shields to block some of light beams from being directed to the plurality of exit lenses, wherein each of the plurality of shields includes a blocking surface to block a light beam from being directed to the plurality of exit lenses and at least one transmission hole formed in the blocking surface.

A lighting apparatus includes a plurality of fiber optic panels coupled to respective light sources. The fiber optic panels include a set of optical fibers configured to emit light transversely to the optical axis thereof to form respective illumination regions in the fiber optic panels. A housing is included in the lighting apparatus to have an internal chamber and at least one window formed therein by which the internal chamber is in optical communication with the exterior of the housing. Additionally, an optical system such as a reflector or lens can subtend the light from the distal ends of the fibers within the chamber. The fiber optic panels are coupled to the housing to convey light into the internal chamber while the illumination regions extend from the housing to perform a lighting function of an automotive vehicle.

The present disclosure relates an integrated module including a camera and a lamp, and may include a camera that acquires an image of a periphery of a vehicle and provide the image, at least one first lamp and at least one second lamp disposed at at least one location of an upper side and a lower side of the camera in a direction of a transverse axis of the camera, and a lamp controller that provides electrical energy for the first lamp to the first lamp and provides electrical energy for the second lamp to the second lamp according to daytime/nighttime determination information based on the image.

A utility rail for a vehicle, includes an inward surface with a utility void, an outward surface opposite to the inward surface, and a light void that is open to the exterior of the utility rail and that is separate from the utility void. A light is received in the light void and has an emitter from which light is emitted from the at least one light void to illuminate an area adjacent to the utility rail. The utility rail may be a one-piece metal extrusion and the light void may be a downward facing channel provided in the extruded rail.

Provided are an auto-regulated vehicle headlamp, an automatic regulation method and a vehicle. The auto-regulated vehicle headlamp includes: a projector assembly capable of projecting infrared rays, configured to project infrared stripes onto a traveling road-surface; the infrared stripes being constituted by alternate bright and dark stripes so that corresponding distorted stripes can be formed when an object, during appearing or disappearing on the traveling road-surface, has a changed contour; a camera configured to capture image information on the distorted stripes; an image processor in data connection with the camera and configured to acquire the image information and generate a headlamp control command accordingly; a matrix headlamp including a plurality of LED light sources; and a first controller in data connection with the matrix headlamp and the image processor, configured to acquire the headlamp control command and adjust the number of the LED light sources to be activated and their brightness.