An LED lighting device includes a transparent cover member arranged at an exterior member or an interior member and covering an LED element and a light emitting surface of the LED element mounted on a substrate, and a light transmission member receiving emission light from the light emitting surface of the LED element at a light inlet end and operating as a light transmission path. The light transmission member is integrated with the LED element mounted on the substrate together with the cover member using a transparent resin by insertion molding.

A light projection lens includes: an inner surface which light emitted from a light source enters, and includes a first concave portion; and an outer surface from which the light exits. In a cross section parallel to an optical axis of the light emitted from the light source, the outer surface and the first concave portion have a difference in radius of curvature in at least a portion of the outer surface and the first concave portion. In a cross section perpendicular to the optical axis of the light emitted from the light source, the first concave portion has an elliptical shape. The light which exits from the outer surface is lesser in amount in an optical axis direction of the light emitted from the light source than in a direction different from the optical axis direction.

To provide a light-emitting unit for a door mirror capable of improving a stability of LED's position and connectivity, while reducing a breakage possibility of the LED due to heat. The light-emitting unit for a door mirror is characterized in that it includes a rigid first substrate part having a connector part to receive a signal, and mounts a control unit thereon to cause an LED to emit light based on the signal; a rigid second substrate part provided separately from the first substrate part and mounts the LED thereon; and a connection part connecting the first substrate part to the second substrate part and having a circuit to cause a current signal transmitted from a first substrate part side to reach the LED's side, and the connection part has lower heat transfer rate than heat dissipation rate of the second substrate part.

The optical assembly disclosed in the embodiment includes a housing having an inclined bottom surface, a plurality of inner surfaces around an outer periphery of the bottom surface, and a receiving space in which an upper portion is opened; and a lighting module disposed on the inclined bottom surface, wherein the lighting module includes a substrate inclinedly disposed on the inclined bottom surface; at least one light emitting device disposed on the substrate; and a resin layer sealing the light emitting device and the substrate, wherein an upper surface of the resin layer emits light by diffusing light emitted from the light emitting device, wherein the plurality of inner surfaces includes a first inner surface adjacent to the light emitting device, a second inner surface facing the first inner surface, and third and fourth inner surfaces facing each other and disposed between the first and second inner surfaces, wherein a height between the bottom surface of the housing and an upper surface of the housing increases from the first inner surface toward the second inner surface, and decreases from the third inner surface toward the fourth inner surface.

An apparatus and method for controlling driving of a vehicle are provided and the apparatus includes a lamp that projects a lamp light onto one of a left floor surface or a right floor surface of the vehicle, a camera that obtains an image of an area onto which the lamp light is projected, and a controller that determines whether to output a warning based on the image of the area onto which the lamp light is projected when the lamp light is projected onto a boundary stone located around at least one of the left floor surface or the right floor surface of the vehicle.

The optical assembly disclosed in the embodiment includes a housing having an inclined bottom surface, a plurality of inner surfaces around an outer periphery of the bottom surface, and a receiving space in which an upper portion is opened; and a lighting module disposed on the inclined bottom surface, wherein the lighting module includes a substrate inclinedly disposed on the inclined bottom surface; at least one light emitting device disposed on the substrate; and a resin layer sealing the light emitting device and the substrate, wherein an upper surface of the resin layer emits light by diffusing light emitted from the light emitting device, wherein the plurality of inner surfaces includes a first inner surface adjacent to the light emitting device, a second inner surface facing the first inner surface, and third and fourth inner surfaces facing each other and disposed between the first and second inner surfaces, wherein a height between the bottom surface of the housing and an upper surface of the housing increases from the first inner surface toward the second inner surface, and decreases from the third inner surface toward the fourth inner surface.

A vehicular door mirror device is provided which includes an engagement claw provided on one of a lamp unit and a mirror housing being engaged with a latching part provided on the other of the lamp unit and the mirror housing, wherein the mirror housing includes a housing main body that has a mirror housing recess part and is pivotably supported by a base member, and a cover that has the slit formed therein and is mounted on the housing main body so as to cover the housing main body from a side opposite to an open direction of the mirror housing recess part, the cover being provided with a restriction part that restricts displacement of the engagement claw toward a direction in which the engagement claw disengages from the latching part. The lamp unit is thus prevented from detaching from the mirror housing even under an external impact.

To provide a light-emitting unit for a door mirror capable of improving a stability of LED's position and connectivity, while reducing a breakage possibility of the LED due to heat. The light-emitting unit for a door mirror is characterized in that it includes a rigid first substrate part having a connector part to receive a signal, and mounts a control unit thereon to cause an LED to emit light based on the signal; a rigid second substrate part provided separately from the first substrate part and mounts the LED thereon; and a connection part connecting the first substrate part to the second substrate part and having a circuit to cause a current signal transmitted from a first substrate part side to reach the LED's side, and the connection part has lower heat transfer rate than heat dissipation rate of the second substrate part.

An apparatus for monitoring the blind spot of a motor vehicle has a mirror assembly with at least one mirror element that can be moved using an actuator, and a microphone assembly. The microphone assembly is designed to determine the sound direction, and the movable mirror element is in the form of a sound reflector.

A lighting device irradiating light to different locations includes a light irradiation unit that generates light; an optical path adjustment unit that adjusts a path of the light radiated from the light irradiation unit to allow a road surface pattern to be formed at a predetermined location on a road surface around a vehicle; and a driving unit that adjusts the optical path adjustment unit to allow the road surface pattern to be formed at different locations on the road surface around the vehicle.