An illuminating vehicle window assembly includes a glass panel, a metallic layer secured to the glass panel, and a light source for illuminating the glass panel to produce an auxiliary brake light within the glass panel. Another exemplary illuminating vehicle window assembly includes a glass panel including a frit area, an optics device formed on the frit area, and a light source for illuminating the glass panel to produce an auxiliary brake light within the glass panel.

A vehicle lighting assembly includes a lighting component, a metallic layer formed on a first portion of the lighting component to establish a reflective surface, a micro-pattern formed on a second portion of the lighting component to establish a non-reflective surface, and a coating that includes a phosphor mixture applied to the micro-pattern.

An illuminating vehicle window assembly includes a glass panel, a metallic layer secured to the glass panel, and a light source for illuminating the glass panel to produce an auxiliary brake light within the glass panel. Another exemplary illuminating vehicle window assembly includes a glass panel including a frit area, an optics device formed on the frit area, and a light source for illuminating the glass panel to produce an auxiliary brake light within the glass panel.

An illuminating vehicle window assembly includes a glass panel, a metallic layer secured to the glass panel, and a light source for illuminating the glass panel to produce an auxiliary brake light within the glass panel. Another exemplary illuminating vehicle window assembly includes a glass panel including a frit area, an optics device formed on the frit area, and a light source for illuminating the glass panel to produce an auxiliary brake light within the glass panel.

A light module includes a plurality of optical fibers configured as an optical fiber panel, wherein a first end of the plurality of optical fibers is configured into a bundle; a first solid state light source coupled to the bundle; a second solid state light source; and a reflector configured to reflect light rays transmitted from the second solid state light source towards the optical fiber panel. A method of transmitting light includes transmitting a first set of light rays, via a first solid state light source, to a plurality of optical fibers of an optical fiber panel, wherein the first solid state light source is coupled to the plurality of optical fibers; transmitting a second set of light rays, via a second solid state light source, towards a reflector; and reflecting the second set of light rays from the reflector towards the optical fiber panel.

A light assembly for a motor vehicle according to an exemplary aspect of the present disclosure includes, among other things, a light source, and a lens arrangement configured to direct light from the light source in a first direction toward a running board and a second direction away from the vehicle. A method is also disclosed.

A lighting assembly that includes an LED source that generates a light cone (solid angle); and a transparent near field lens having a front surface, a collimating surface, and an aspherical groove. The collimating surface collimates the light cone into a beam that reflects off of the front surface toward the aspherical groove, and the aspherical groove directs the beam away from the lens as an exit cone from a virtual focal point, positive virtual focal ring or a negative virtual focal ring. The exit cone may be evenly distributed, substantially forward or substantially rearward from the virtual focal point or virtual focal ring. Parabolic or aparabolic reflectors can be employed with lighting assemblies having a virtual focal point or virtual focal ring, respectively, to reflect the exit cone in a vehicular exterior lighting pattern.

A lighting assembly that includes an LED source that generates a light cone (solid angle); and a transparent near field lens having a front surface, a collimating surface, and an aspherical groove. The collimating surface collimates the light cone into a beam that reflects off of the front surface toward the aspherical groove, and the aspherical groove directs the beam away from the lens as an exit cone from a virtual focal point, positive virtual focal ring or a negative virtual focal ring. The exit cone may be evenly distributed, substantially forward or substantially rearward from the virtual focal point or virtual focal ring. Parabolic or aparabolic reflectors can be employed with lighting assemblies having a virtual focal point or virtual focal ring, respectively, to reflect the exit cone in a vehicular exterior lighting pattern.

An embodiment may include a complex lighting for a vehicle. The complex lighting may include a first lighting unit configured to include a first light source module, and a first reflection module having an inlet portion of an incidence light of the first light source module, a light transfer path through which the incidence light transfers and an outlet portion of the incidence light. The complex lighting may also include a second lighting unit configured to be disposed adjacently to the first lighting unit, and to receive the light of the outlet portion of the first lighting unit and then control the amount of light emission. A bottom inside of the first reflection module may include a curvature area.

An embodiment may include a complex lighting for a vehicle. The complex lighting may include a first lighting unit configured to include a first light source module, and a first reflection module having an inlet portion of an incidence light of the first light source module, a light transfer path through which the incidence light transfers and an outlet portion of the incidence light. The complex lighting may also include a second lighting unit configured to be disposed adjacently to the first lighting unit, and to receive the light of the outlet portion of the first lighting unit and then control the amount of light emission. A bottom inside of the first reflection module may include a curvature area.