A lighting system of a vehicle may include light units and controllers for operating the light units. Each light unit is multifunctional in that the light unit may operate in various modes, which may be invoked at different times under varying circumstances. A light unit on the first end of a vehicle may operate as a headlight if the first end is the front end of the vehicle. On the other hand, the light unit may operate as a tail light if the first end is the rear end of the vehicle. Furthermore, the light unit may operate as a turn signal in either direction or brake light while the first end is the rear end of the vehicle. The light unit includes a lens array positioned to receive light from various light sources. The lighting system may operate in a fashion that allows for lighting redundancy on each end of the vehicle in the event of a lighting controller failure.

An illumination system includes an illumination control unit which is configured to change the illumination state of each of a left-side illumination unit (40L), a left-side auxiliary illumination unit (42L), a right-side illumination unit (40R), and a right-side auxiliary illumination unit (42R). The illumination control unit is configured to change the illumination state of the left-side illumination unit (40L) when a vehicle (1) has detected a pedestrian (P). The illumination control unit is configured to change the illumination state of the left-side auxiliary illumination unit (42L) according to the speed of the vehicle (1). The illumination control unit is configured to change the illumination state of each of light emission segments (43L) of the left-side illumination unit (40L) and each of light emission segments (44L) of the left-side auxiliary illumination unit (42L).

A vehicle lamp includes a light source unit including a first light source and a second light source, a reflector which includes a plurality of first reflecting surfaces sharing a first focal point at a position corresponding to the first light source and a plurality of second reflecting surfaces sharing a second focal point at a position corresponding to the second light source, and which has a shape by which the first reflecting surfaces and the second reflecting surfaces diffuse a white light from the first light source and an orange light from the second light source in the right-left direction in an in-vehicle state, and an inner lens that emits the white light and the orange light reflected by the plurality of first reflecting surfaces and the plurality of second reflecting surfaces from a common emission surface to the front of a vehicle.

A lighting system of a vehicle may include light units and controllers for operating the light units. Each light unit is multifunctional in that the light unit may operate in various modes, which may be invoked at different times under varying circumstances. A light unit on the first end of a vehicle may operate as a headlight if the first end is the front end of the vehicle. On the other hand, the light unit may operate as a tail light if the first end is the rear end of the vehicle. Furthermore, the light unit may operate as a turn signal in either direction or brake light while the first end is the rear end of the vehicle. The light unit includes a lens array positioned to receive light from various light sources. The lighting system may operate in a fashion that allows for lighting redundancy on each end of the vehicle in the event of a lighting controller failure.

There are disclosed video systems and methods that use a camera in a lamp housing for a tractor-trailer. Within the housing is an electrical subsystem with a PLC interface and an electrical connector disposed outside the housing and adapted to connect to the trailer and draw power therefrom. A lamp mounted in the housing is connected and adapted to draw power through the electrical subsystem and emit light through a cover of the housing. The camera mounted in the housing has a field of view through the cover. The camera is connected and adapted to draw power through the electrical subsystem and to capture images through the cover and is further connected to the PLC interface. The PLC interface converts data from the camera and transmits the converted data through the electrical connector to the trailer.

Methods and systems for providing Advanced Driver Assistance System (ADAS) warnings and/or other types of information to an occupant of a motor vehicle are provided. Warning lights can be provided around the perimeter of a shape that represents the perimeter of the vehicle from a top-view perspective. Lights around the shape can be lit to convey a sense of the area of danger and/or the direction from which danger is approaching.

System and methods are provided for detecting vibrations of one or more object in a scene comprising at least one illumination source configured to project light in a structured light pattern on the scene; a Time-of-Flight (ToF) imaging device comprising: an illumination source configured to project modulated light into the scene, a ToF sensor, configured to capture a plurality of images comprising reflections of the modulated light, the structured light pattern from the one or more objects in the scene and ambient light images of one or more objects in the scene; and at least one processor configured to: extract depth data of said one or more objects by analyzing the plurality of images and analyze one or more changes in one or more speckle patterns of at least one of the reflections of said structured light pattern in at least some consecutive images of the plurality of images; and identify the vibrations of the at least one object based on said speckle pattern analysis and said depth data.

A lighting assembly and method generate a three-dimensional lighting effect with parallax, depth and brightness variability or twinkling among different viewing angles using an LED substrate and different optic component layers including one or more obscuration patterns and a reflection chamber for unobscured light from LEDs components not obscured by the one or more obscuration patterns. The LED substrate can employ mini or micro scale package LEDs or their unpackaged LED dies for slim profile lighting assembly. The LED substrate and different optic component layers can be curved, employ direct illumination and occultation imaging.

A lighting apparatus includes light emitting elements having an emission peak wavelength of 400 to 510 nm, a first phosphor having an emission peak wavelength of 485 to 700 nm, a second phosphor having an emission peak wavelength of 510 to 590 nm, a third phosphor having an emission peak wavelength of 600 to 700 nm, and a color filter having transmittance for light with a wavelength of 600 to 730 nm that is 80% or more and transmittance for light with a wavelength of 410 to 480 nm that is 3% or more and 50% or less. The color filter transmits a part of light emitted from the first phosphor, at least a part of light emitted from the second phosphor, and at least a part of light emitted from the third phosphor. Light transmitted through the color filter is emitted to the outside.

A reflector unit may behave as a retroreflector to reflect light of a selected color. The reflector unit may comprise a first reflector having a first color, a second reflector having a second color, and a mask that either allows incoming light to reach the first reflector and not the second reflector or allows incoming light to reach the second reflector and not the first reflector. An active light unit may emit light of a particular color in response to receiving light. In this fashion, the active light unit may simulate the operation of a reflector. The reflector unit and the active light unit may operate on a bi-directional vehicle.