LED related lighting methods and apparatus are described. Various features relate to water tight light fixtures. Some of the fixtures are spotlights while other fixture are intended for in ground use. The light fixtures in at least some embodiments include power control features. In spotlight embodiments beam angle and power or light output can be controlled without opening the light assembly or compromising the water tight seals which also protect against dirt. In ground embodiments support tilt angle setting which allow a user to set the light fixture to one or more tilt angles. Beam angle can also be changed in some embodiments as well as power control. Beam angle, power control and tilt angle adjustments are supported in some embodiments but need not be supported in all embodiments with some embodiments using one or more of the described features but not all features.

A biological lighting system to provide temporally- and spatially-modulated photon flux output and spectral power distributions to plants on a circadian and circannual basis, or circadian and life cycle basis, to maximize effective and efficient growth in a horticultural setting. The photon flux or irradiance output and the spectral power distribution are modulated to match circadian and circannual rhythms, with individual or multiple luminaires controlled through one or more controllers. Different lighting spectra can be employed depending on the direction of illumination. The photon flux or irradiance output and the spectral power distribution may be set as best suited for any particular plant species, and the system is also useful for raising animals.

An on-board infrared illumination device includes an infrared light source that provides for-camera infrared illumination by irradiating, with infrared radiation, a plurality of irradiation areas included in an imaging range within an exposure time of an on-board infrared camera, a light source controller configured to control the infrared light source to form a plurality of irradiation patterns at a timing different from a timing for the for-camera infrared illumination, and an infrared sensor. Each irradiation area is formed such that one or more different irradiation areas among the plurality of irradiation areas are selectively irradiated with the infrared radiation. The light source controller controls the infrared light source to adjust an illuminance of the for-camera infrared illumination on each irradiation area independently of each other on the basis of a sensor signal output from the infrared sensor for each of the plurality of irradiation patterns.

A lamp includes a heat radiating housing, an LED terminal seat mounted in the heat radiating housing, an LED light mounted in the LED terminal seat, a positioning seat mounted on the LED terminal seat, a mounting seat mounted on the positioning seat, a focus adjusting seat mounted on the positioning seat and corresponding to the mounting seat, and a lens mounted in the mounting seat. The positioning seat has an inner face provided with two guide grooves extending in a spiral direction. The focus adjusting seat is provided with two directing slots. The mounting seat has an outer face provided with two guide pins locked in the two directing slots. The two guide pins are slidably mounted in the two guide grooves.

A lamp includes a heat radiating housing, an LED terminal seat mounted in the heat radiating housing, an LED light mounted in the LED terminal seat, a positioning seat mounted on the LED terminal seat, a mounting seat mounted on the positioning seat, a focus adjusting seat mounted on the positioning seat and corresponding to the mounting seat, and a lens mounted in the mounting seat. The positioning seat has an inner face provided with two guide grooves extending in a spiral direction. The focus adjusting seat is provided with two directing slots. The mounting seat has an outer face provided with two guide pins locked in the two directing slots. The two guide pins are slidably mounted in the two guide grooves.

A light emitting module with a reduced thickness is provided. A method of manufacturing a light emitting module sequentially includes: providing a light guiding plate having a first main surface being a light emitting surface, and a second main surface on the side opposite to the first main surface; providing a plurality of light emitting elements on the light guiding plate; and forming a wiring electrically connecting the plurality of light emitting elements. A light emitting module includes: a light guiding plate having a first main surface and a second main surface; a plurality of wavelength conversion parts disposed at the second main surface of the light guiding plate so as to be spaced apart from each other; a plurality of light emitting elements respectively bonded to the plurality of wavelength conversion parts; and a wiring connected to the plurality of light emitting elements.

A vehicle grille assembly is disclosed that is passively illuminated by accent lighting sources provided in a corresponding headlamp assembly. A primary light guide in communication with a light source and a secondary light guide is disposed within the vehicle grill. The secondary light guide receives light from the primary light guide to illuminate a portion of the vehicle grille.

An illumination device with a projector includes a base, a shade having a side-surface shade surrounding an outer circumferential side of the base, an upper-surface shade disposed above the base, and a lower-surface shade disposed below the base, a projector which is installed on the base, and projects image light toward the side-surface shade, and an illumination unit for illuminating the upper-surface shade and the lower-surface shade from inside the shade. The side-surface shade is provided with a mirror surface part for reflecting light which shines on the side-surface shade from the outside. The mirror surface part is provided with an image light transmission part which the image light enters. The image light transmission part is a semi-transmissive mirror. Therefore, the image light can be projected via the semi-transmissive mirror, but a projection opening of the projector is not seen from the outside.

An illumination device with a projector includes a base, a shade having a side-surface shade surrounding an outer circumferential side of the base, an upper-surface shade disposed above the base, and a lower-surface shade disposed below the base, a projector which is installed on the base, and projects image light toward the side-surface shade, and an illumination unit for illuminating the upper-surface shade and the lower-surface shade from inside the shade. The side-surface shade is provided with a mirror surface part for reflecting light which shines on the side-surface shade from the outside. The mirror surface part is provided with an image light transmission part which the image light enters. The image light transmission part is a semi-transmissive mirror. Therefore, the image light can be projected via the semi-transmissive mirror, but a projection opening of the projector is not seen from the outside.

A vehicle headlight includes a low beam light module and a appearance light module, which are embodied, arranged and designed such that, in a low beam mode, less than 30% of the light intensity emitted by the vehicle headlight with respect to a vertical orientation above the light-shadow line and with respect to the horizontal orientation in the direction of travel, is generated by the low beam light module.