A cylindrical electrode module of a fiber optic laser system includes an inner cylinder having an inner repeating pattern of longitudinally-aligned positive and negative electrodes on an outer surface of the inner cylinder. The cylindrical electrode mode includes an outer cylinder that encloses the inner cylinder. The outer cylinder that has an outer repeating pattern of longitudinally-aligned negative and positive electrodes on an inner surface of the inner cylinder that are in corresponding and complementary, parallel alignment with the positive and negative electrodes of the inner repeating pattern on the outer surface of the inner cylinder. The cylindrical electrode module includes an optical fiber having an input end configured to align with and be optically coupled to a high power pump laser. The optical fiber is wrapped around the inner cylinder within the outer cylinder to form a cylindrical fiber assembly. The electrodes are activated to achieve quasi-phase matching.

Lamp shades are provided with ornamentation utilizing light pipes and fiber optics, using light pipe technology to provide an ornamented shade. For lampshades of the truncated conical shape type, this light pipe ornamentation includes light emitting top and/or bottom circular rims, as well as an optional light emitting central thematic character/logo figure in 3D relief. Light is transmitted from the interior of the shade to illuminate the light pipe features, or from fiber optic electrically conductive wires/cables, which may include circular light pipes attached as integrally formed top and bottom rims of the lamp shade. Alternatively, the circular decorative light pipes may be formed by a plurality of arcuate segments, which, when joined together, form a circular rim, where light may be diffused and sent through the segments. The translucent light pipe elements may be injection molded of tinted light guide grade plastic resin.

An illuminated guide pole for a watercraft-supporting structure includes an elongate LED light source enclosed within a waterproof housing mounted to the supporting structure. The housing includes a transparent pipe for surrounding the LED light source. The light source is electrically connected to a source of power and may include an LED whip light device.

A color conversion element includes: a phosphor layer that includes at least one type of phosphor; a reflecting layer stacked on the phosphor layer; a substrate disposed in a position opposite to the reflecting layer; a joining portion interposed between the reflecting layer and the substrate for joining the reflecting layer and the substrate; and an absorbing portion disposed above a principal surface of the substrate closer to the joining portion. The absorbing portion is covered with the joining portion and absorbs laser light having a wavelength that excites the phosphor.

The application provides an improved gemstone testing apparatus for testing a gemstone specimen. The gemstone testing apparatus includes a handheld casing, a processor unit, a first gemstone test device, a second gemstone test device, and a display unit. The first gemstone test device includes a first test probe and a thermal conductivity test module. The second gemstone test device includes a second test probe and a light absorption module.

A concealed light fixture sign includes a flange having stencil openings formed therein that define a message. A container extends from a rear surface of the flange and provides light through the stencil openings. The container is configured to be installed completely within a recess behind a mounting surface with the flange positioned substantially flush with the mounting surface. Translucent inserts positioned within the stencil openings are removable to provide access to an interior of the container after installation of the light fixture sign.

Device for printing three-dimensional objects using an energy-field projection system. In operation, energy is projected into a print medium according to a four dimensional (4D) energy-field function for exposing the print-medium to a threshold energy-intensity level that causes the print medium to harden in the shape of a three-dimensional object.

The application provides an improved gemstone testing apparatus for testing a gemstone specimen. The gemstone testing apparatus includes a handheld casing, a processor unit, a first gemstone test device, a second gemstone test device, and a display unit. The first gemstone test device includes a first test probe and a thermal conductivity test module. The second gemstone test device includes a second test probe and a light absorption module.

An optoelectronic apparatus is presented. In embodiments, the apparatus may include a package including a substrate with a first side and a second side opposite the first side, wherein the first side comprises a ball grid array (BGA) field. The apparatus may further include one or more integrated circuits (ICs) disposed on the first side of the substrate, inside the BGA field, that thermally interface with a printed circuit board (PCB), to which the package is to be coupled, one or more optical ICs coupled to the second side and communicatively coupled with the one or more ICs via interconnects provided in the substrate, wherein at least one of the optical ICs is at least partially covered by an integrated heat spreader (IHS), to provide dissipation of heat produced by the at least one optical IC.

A light-emitting module structure comprises a support substrate and a micro-module disposed on or in the support substrate that extends over only a portion of the support substrate. The micro-module comprises a rigid module substrate, an inorganic light-emitting diode, a power source, and a control circuit. The inorganic light-emitting diode, the power source, and the control circuit are disposed on or in the module substrate and the control circuit receives power from the power source to control the inorganic light-emitting diode to emit light. A light conductor is disposed on or in the support substrate and in alignment with the micro-module so that the inorganic light-emitting diode is disposed to emit light into the light conductor and the light conductor conducts the light beyond the micro-module to emit the light from the light conductor.