An underwater light probe includes a body, a heat sink, and a lens assembly. The heat sink forms at least a portion of the body and includes a longitudinally extending mounting base having a plurality of laterally facing mounting surfaces configured to mount a plurality of laterally facing light elements thereon. The lens assembly is configured to couple to the body and defines a bore configured to receive the longitudinally extending mounting base and the plurality of laterally facing light elements mounted thereon and provide a watertight seal therearound when coupled to the body.

An underwater light probe includes a body, a heat sink, and a lens assembly. The heat sink forms at least a portion of the body and includes a longitudinally extending mounting base having a plurality of laterally facing mounting surfaces configured to mount a plurality of laterally facing light elements thereon. The lens assembly is configured to couple to the body and defines a bore configured to receive the longitudinally extending mounting base and the plurality of laterally facing light elements mounted thereon and provide a watertight seal therearound when coupled to the body.

A lighting device is disclosed with excitation light source(s) for emitting excitation light along an excitation light path; a wavelength conversion assembly including wavelength conversion element(s) for converting the excitation light into conversion light and emitting it into the same half-space from which the excitation light is radiated onto the surface of the element, and reflection element(s) for reflecting, in unconverted fashion, the excitation light intermittently radiated onto the reflection element from the source(s) along the portion of the excitation light path onto a reflection light path as reflection light; and a dichroic mirror for deflecting the excitation light coming from the source(s) onto the portion of the excitation light path on which the excitation light is radiated onto the wavelength conversion element(s) or the reflection element(s). The mirror is configured such that the conversion light is transmitted through the mirror and the reflection light is guided past the mirror.

of the Invention. Disclosed herein an apparatus for mimicking the light and sky-conditions at the horizon comprises a light assembly (2) provided with at least two angularly disposed horizontal strips (9a and 9b) of light source, a composite lens (5) fixedly placed above the light assembly (2) and configured to selectively reflect and transmit the light incident on it, a reflecting dome (3) centrally and partially disposed over the composite lens (5) and light assembly module (2) and provided with an LED spotlight (12) under it, a mounting bracket (4) adapted to receive the light assembly and the composite lens; and a controller (11) configured to control and monitor one or more predetermined parameters of the light source (9), wherein the characteristic of the composite lens (5) is translated depending on the desired geographical location. A corresponding method for mimicking the light and sky-conditions at the horizon is also disclosed.

of the Invention. Disclosed herein an apparatus for mimicking the light and sky-conditions at the horizon comprises a light assembly (2) provided with at least two angularly disposed horizontal strips (9a and 9b) of light source, a composite lens (5) fixedly placed above the light assembly (2) and configured to selectively reflect and transmit the light incident on it, a reflecting dome (3) centrally and partially disposed over the composite lens (5) and light assembly module (2) and provided with an LED spotlight (12) under it, a mounting bracket (4) adapted to receive the light assembly and the composite lens; and a controller (11) configured to control and monitor one or more predetermined parameters of the light source (9), wherein the characteristic of the composite lens (5) is translated depending on the desired geographical location. A corresponding method for mimicking the light and sky-conditions at the horizon is also disclosed.

The present invention provides a lens and an illuminating device including the lens, wherein the lens includes a first lens part and a second lens part, the second lens part is provided around the first lens part, the first lens part and the second lens part are provided in an enclosed manner to form a light emitting part and an accommodating part for accommodating a light source, the light emitting part and the accommodating part locate on two opposite sides of the first lens part, and a surface of the first lens part facing the light emitting part is provided with a plurality of concentrically-arranged annular bulges so as to change the angles of lights according to a location of the light source in the accommodating part. The technical solution of the present invention can change a light emitting angle so as to adapt to use requirements of different near and far occasions.

A precision approach path indicator (PAPI) employs an LED light source with first and second arrays of LEDs or other efficient light sources, disposed one above the other and emitting their respective color lights along an optic axis to a collimating lens of focal length f. First and (optional) second aperture plates positioned along the optic axis, each being a respective frame with a cut-out defining a horizontally elongated aperture for light passing along the optic axis. Intermediate aperture plate(s) can be positioned between the first and second aperture plates. The first frame is positioned between the light source and the collimating lens at the focal distance f from the lens. The optional second aperture plate is positioned at the collimating lens and covers top, bottom, and side edge portions of the lens. A planar blade extends from the light source to the first frame and has a distal edge extending across the aperture of the first aperture plate, substantially at the focus of the collimating lens, dividing the beam into white and red sectors. The intermediate aperture plate(s) can be adjusted for optimal separation. The PAPI can be considered to have an illumination portion formed of the light source(s), blade, and first frame; and an imaging portion formed of an enclosure and a lens positioned at its focal length distant from the front frame aperture and edge of the blade.

Optical apparatus includes a semiconductor substrate and one or more radiation sources, mounted on a surface of the substrate and configured to emit optical radiation. A scanning mirror is mounted on the substrate and is configured to scan the reflected optical radiation over a predetermined angular range in a direction that is angled away from the surface.

Optical apparatus includes a semiconductor substrate and one or more radiation sources, mounted on a surface of the substrate and configured to emit optical radiation. A scanning mirror is mounted on the substrate and is configured to scan the reflected optical radiation over a predetermined angular range in a direction that is angled away from the surface.