The present disclosure relates to a vehicle indicator lighting assembly or other lighting device for providing dual-color outputs in a lit state and an unlit state, respectively. Specifically, a color of a lighting device may be controlled such that an unlit state may communicate a desired color corresponding to a surface of a component of the lighting device. For instance, the lighting device can include a light guide having one or more decoupling regions and a bezel having one or more effecting facets arranged relative to the light guide. The light guide may be optically-coupled to a light source. The one or more effecting facets may be designed such that, when the lighting device is not illuminated by the light source, a color of a surface of the one or more effecting facets is displayed to an observer in a trailing vehicle by reflection of ambient light from an environment external to the vehicle.

A vehicle lamp system based on a PBS (Polarization Beam Splitter) is provided, including a light source, the PBS, a collimating lens set, an imaging lens set, an LCOS (Liquid Crystal on Silicon) control chip and a light path control unit. The collimating lens set and the PBS are successively arranged along a light emission direction of the light source. The LCOS control chip is arranged at a light path of an S wave reflected by a contact surface of the PBS. The imaging lens set is arranged at an emergent light path of the S wave after being modulated by the LCOS control chip and transmitted through the contact surface of the PBS. The light path control unit is arranged at a light path of a P wave transmitted through the contact surface of the PBS. Through the light path control unit, utilization of a light energy is improved.

The present invention provides a lamp for a vehicle including a housing in which an open surface is formed, a first substrate on which a light source is mounted and which is disposed in the housing such that the light source faces the open surface, a second substrate electrically connected to the first substrate and perpendicularly coupled to the first substrate, a terminal part coupled to an end portion of the second substrate to be in contact with a terminal of a socket connected to an external power source, and a lens coupled to the housing to cover the open surface, and thus may provide an advantageous effect in that areas of a heat sink and the substrate are minimized while electrical connectivity is secured.

A lighting device according to one embodiment comprises: a housing having an opening; a half mirror member arranged in the opening; a first light source unit for emitting light at the half mirror member; a mirror member for re-reflecting light reflected by the half mirror member; a diffusion plate arranged between the first light source unit and the half mirror member; and a guide unit protruding from the lower surface of the housing, wherein the housing includes a first area and a second area formed by the guide unit, the first light source unit is arranged in the first area and the mirror member is arranged in the second area, and the diffusion plate can be supported by the guide unit. Therefore, the lighting device can implement various three-dimensional effects of an optical image according to a field of view by using the half mirror member and the mirror member during lighting.

An opening and closing system includes a first human detection sensor configured to detect a vehicle user who enters a first area defined on a periphery of a vehicle body, a lamp visible by the vehicle user who enters the first area, and a control device configured to control an unlocking operation of the lock device, a closing operation of the striker device, a pop-up operation of the striker device, and switching on and off of the lamp. The control device switches on the lamp when the vehicle user is detected by the first human detection sensor and starts the controlling of the unlocking operation of the lock device and the closing operation and the pop-up operation of the striker device in response to the lamp being switched on.

A combination rear lamp is revealed. A light emitting unit is disposed in a mounting space formed between a lamp base and a lamp cover. A plurality of light emitting diodes (LEDs) is arranged at a substrate of the light emitting unit. A transparent first area is formed on a middle part of the lamp cover and a translucent second area is formed around the first area. A light guide bar is located directly under the first area and its length is longer than that of the first area. Two LEDs that emit white light are corresponding to light incident parts on two sides of the light guide bar respectively. Thereby white light emitted and transmitted through the light guide bar and the first area of the lamp cover is projected in a three-dimensional sense. The LEDs and light spot emitted will not be seen through the lamp cover.

A small-vehicle direction indicator device includes a directional signal light for small vehicles, such as saddle riding type vehicles, the directional signal light including a lighting unit and a plurality of light sources that are arrayed in the lighting unit in a vehicle width direction. The small-vehicle direction indicator device performs a dynamic direction indication by chain-reactive switch-ons or switch-offs of the plurality of light sources when the directional signal light is activated. In the directional signal light, between the plurality of light sources, a light-blocking wall made of an opaque member is arranged, and wherein a plurality of the light-blocking walls are arrayed in the vehicle width direction.

The purpose of the present invention is to provide a go-kart which is equipped with an LED light fixture that can efficiently shine light below the vehicle. This go-kart is equipped with: a vehicle body frame that supports an engine, front wheels, and rear wheels, and is exposed to the exterior; and elongated strips of LED tape that are affixed to both the left and right sides of the vehicle body frame extending in the front-rear direction, and shine light below the vehicle body frame. In addition, the front wheels and rear wheels are supported on the outer side of the vehicle body frame. When the front-side end of the vehicle is viewed from the left-right direction, the LED tape and the LED tape extend to positions which overlap with the front wheels, and when the rear-side end of the vehicle is viewed from the left-right direction, the LED tape and the LED tape extend to positions which overlap with the rear wheels.

An electronic control module of a light source includes at least one circuit card supporting electronic components and configured to be received by a first of its edges in a housing. The control module has in the vicinity of the first edge a connecting portion including at least one rib perpendicular or substantially perpendicular to the plane defined by the circuit card.

A laser illumination device includes a light source component, a micro-element lens, and a meniscus lens. The light source component emits a laser beam. The micro-element lens spreads out the laser beam. The meniscus lens has an incident face on which the laser beam from the micro-element lens is incident, and a light emission face that is provided on the opposite side from the incident surface and includes a convex shape, and the meniscus lens has a negative power for spreading out the incident laser beam from the micro-element lens.