An auxiliary lighting system for a three-wheeled motorcycle having a pair of rear wheels is disclosed, wherein the lighting system is affixed to a forward-facing portion and/or side portion of the rear fenders thereof.

A lighting assembly for vehicles, having a number of light sources and light guide elements for generating different light functions, with a number of scattering optical elements assigned to the light exit side of the light guide elements for scattering the light. A headlamp lens is arranged at a distance in front of the light guide elements. The first light sources and the second light sources are arranged alternately in the direction of extension of the linear light signature. The scattering optical elements and/or the distance of the headlamp lens to the scattering optical elements and/or a distance in between adjacent first light sources running in the direction of extension are designed such that first light beams exiting in each case from the scattering optical elements assigned to the adjacent first light sources and adjacent in the direction of extension.

A lamp unit in which an opening of a unit case is covered with an outer lens is provided. The lamp unit includes a first inner lens provided inside the outer lens, a second inner lens provided inside the outer lens, a first light source facing an incident surface of the first inner lens, and a second light source facing an incident surface of the second inner lens. A space inside the first inner lens and a space inside the second inner lens are continuous. At least a part of the incident surface of the second inner lens is disposed in an irradiation range of the first light source.

A vehicle luminaire according to an exemplary embodiment includes: a socket includes a flange, a mounting part, and contains a highly heat conductive resin; a light-emitting module includes at least one light-emitting element; and a heat transfer part is provided between the mounting part and the light-emitting module. An expression of 2.5 [watt]≤WT≤5.5 [watt], an expression of 15 [watt/(m.Math.K)]≤WT≤25 [watt/(m.Math.K)], and an expression of 40 [1/K]≤(A1−A2)×WT/W≤90 [1/K] are satisfied. W [watt] represents electric power that is applied to the light-emitting module. WT [watt/(m.Math.K)] represents heat conductivity of the highly heat conductive resin. A1 [mm] represents a dimension of the flange in a direction orthogonal to a central axis of the vehicle luminaire. A2 [mm] represents a dimension of the mounting part in a direction orthogonal to the central axis of the vehicle luminaire.

A lamp control device includes: at least two lamps; a lamp ECU provided in each of the at least two lamps and configured to perform a lamp control on the each of the at least two lamps; and a vehicle ECU configured to communicate a control signal to the lamp ECU. The vehicle ECU is connected to the lamp ECU via a first high-speed communications line. The lamp ECU is configured to independently perform a lamp control by communication through the first high-speed communications line.

A vehicular luminaire according to embodiments includes a socket; a substrate provided on the socket and including a wiring pattern on at least one surface; at least one light-emitting element electrically connected to the wiring pattern; and a plurality of power-supply terminals extending inside the socket and including one end portion exposed from the socket, the vicinity of the end portion being bent toward the substrate.

A lighting device for a motor vehicle includes a lighting apparatus which has one or more light sources and one or more transparent bodies which each have a surface made of a plurality of flat facets. The lighting device is configured such that light which comes from a light source at least in part passes through a transparent body and is refracted at facets of the transparent body. The light which passes through the transparent body at least in part exits from the lighting device in order to create a light distribution. An associated transparent body is a molded component having one or more recesses which are integrally molded in the molded component, the molded component being clamped in the lighting device by the engagement of one or more projections into the one or more recesses.

A second light source, a second incidence section and a second reflecting section in a vehicle lamp are disposed closer to a light guide section than a first light source, a first incidence section and a first reflecting section, a stepped section is provided between the first reflecting section and the second reflecting section, and the first reflecting section is disposed at above the stepped section and the second reflecting section is disposed at below the stepped section when seen from a side of the first incidence section and a side of the second incidence section.

An illuminating device for vehicles, including an elongated light guide, which has an end face for coupling light into the light guide and has a lateral surface, at which the coupled-in light may be totally reflected in a coupling direction. An elongated reflector is arranged so that it follows the light guide and at least partially behind the light guide in the main emission direction. The light guide is designed such that the coupled-in light is coupled out on a rear-side lateral surface and/or side lateral surface facing the reflector and on a front lateral surface facing away from the reflector. The light guide and the reflector each have a corner region, in which sections of the light guide and sections of the reflector enclose an acute or right or obtuse angle.

Provided is a vehicle signal light in which a person with protanopia (p-type color vision deficiency) can perceive whether or not the vehicle signal light, e.g., a stop lamp, a tail lamp, or the like, is turned on. The vehicle signal light includes a first light source configured to emit red light and a second light source configured to emit amber light. The first light source and the second light source are simultaneously turned on and are configured to emit light with a higher luminous intensity in response to a braking operation, and the emission intensity of the first light source is higher than that of the second light source.