An airport runway approach lighting apparatus is disclosed. According to one embodiment. the airport runway approach light includes a visible light source configured to emit a visible light brain and an infrared light source configured to emit an infrared beam. A first lens is attached to the visible light source to change the visible light beam emitted from the visible light source to a desired visible light beam pattern. The infrared light source includes a plurality of semiconductor laser diodes distributed on a surface of a laser diode chip in an array.

A TO-type optical element package for high-speed communication which is used for an optical module for high-speed communication of at least 10 gigabits per sec (Gbps) and enables thermoelectric elements to be embedded in an upper part of a stem. The TO-type optical element package for high-speed communication can transmit high-quality signals in a high-speed operation of the optical element by inserting and fixing an electrode pin (120) in a through-hole formed on a stem base (100), surrounding a lateral surface of the electrode pin (120) protruding to an upper part of the stem base (100), with a metallic instrument (400) having a through-hole so as to enable the impedance of an electrode pin (120) part, surrounded with the stem base (100), to correspond to the impedance of an electrode pin (120) part protruding to the upper part of the stem base (100).

A light emission device includes: a plurality of semiconductor light-emitting elements; an optical element configured to collimate light emitted from each of the plurality of semiconductor light-emitting elements and output a plurality of collimated beams; a converging portion having a surface of a hyperboloid or a paraboloid configured to converge the plurality of collimated beams; and a wavelength-converting portion including a transmissive region, and a reflective region that surrounds the transmissive region, the transmissive region including a light-incident surface at which the plurality of collimated beams that have been converged by the converging portion enter, wherein the transmissive region includes a phosphor adapted to be excited by the plurality of collimated beams that have been converged by the converging portion.

A light emission device includes: a plurality of semiconductor light-emitting elements; an optical element configured to collimate light emitted from each of the plurality of semiconductor light-emitting elements and output a plurality of collimated beams; a converging portion having a surface of a hyperboloid or a paraboloid configured to converge the plurality of collimated beams; and a wavelength-converting portion including a transmissive region, and a reflective region that surrounds the transmissive region, the transmissive region including a light-incident surface at which the plurality of collimated beams that have been converged by the converging portion enter, wherein the transmissive region includes a phosphor adapted to be excited by the plurality of collimated beams that have been converged by the converging portion.

The object is to provide a technique that allows a semiconductor laser to be efficiently cooled. A semiconductor laser light source device includes: a semiconductor laser; a cooler that cools the semiconductor laser; and a driving substrate that drives the semiconductor laser. The cooler is placed in contact with a surface of the semiconductor laser that is opposite to a light emitting surface of the semiconductor laser. Furthermore, the driving substrate is placed in contact with a surface of the cooler that is opposite to a surface of the cooler on which the semiconductor laser is placed.

Materials containing picocrystalline quantum dots that form artificial atoms are disclosed. The picocrystalline quantum dots (in the form of born icosahedra with a nearly-symmetrical nuclear configuration) can replace corner silicon atoms in a structure that demonstrates both short range and long-range order as determined by x-ray diffraction of actual samples. A novel class of boron-rich compositions that self-assemble from boron, silicon, hydrogen and, optionally, oxygen is also disclosed. The preferred stoichiometric range for the compositions is (B.sub.12H.sub.w).sub.xSi.sub.yO.sub.z with 3≤w≤5, 2≤x≤4, 2≤y≤5 and 0≤z≤3. By varying oxygen content and the presence or absence of a significant impurity such as gold, unique electrical devices can be constructed that improve upon and are compatible with current semiconductor technology.

An eye-safe optoelectronic module includes a light source mounted on a support and operable to generate light along an emission axis. An eye-safe substrate has an eye-safe substrate refractive index and includes at least one diffusive surface. The eye-safe substrate is mounted such that the emission axis is intercepted by the diffusive surface. An optical assembly includes at least one optical element, is composed of an optical material and is mounted on the diffusive surface of the eye-safe substrate such that the optical material fills a diffusive surface of the eye-safe substrate. The optical assembly has an optical assembly refractive index that is substantially the same as the eye-safe substrate refractive index.

A light emitting device includes a submount, a semiconductor laser device, and a base supporting the submount. The submount includes a graphite layer having upper and lower surfaces extending in first and second directions orthogonal to each other and a support layer having upper and lower surfaces extending in the first and second directions. The graphite layer includes a plurality of graphene structures layered in the first direction. Each of the plurality of graphene structures extends in the second direction. The support layer is thicker than the graphite layer. The upper surface of the support layer supports the lower surface of the graphite layer. The semiconductor laser device emits laser light through an end surface in the first direction. The semiconductor laser device includes a waveguide that extends in the first direction and is supported by the upper surface of the graphite layer.

A packaged integrated white light source configured for illumination and communication or sensing comprises one or more laser diode devices. An output facet configured on the laser diode device outputs a laser beam of first electromagnetic radiation with a first peak wavelength. The first wavelength from the laser diode provides at least a first carrier channel for a data or sensing signal.

A light-emitting device includes: a semiconductor laser element; a supporting member located above the semiconductor laser element, the supporting member having a through-hole that allows light emitted from the semiconductor laser element to pass therethrough; a fluorescent member located in the through-hole, the fluorescent member containing a fluorescent material that is excitable by light emitted from the semiconductor laser element so as to emit light having a wavelength different from a wavelength of the light emitted from the semiconductor laser element; and a light-transmissive heat dissipating member including: a base portion, and a projecting portion projecting from the base portion into the through-hole. An upper surface of the projecting portion of the heat dissipating member is bonded to a lower surface of the fluorescent member. An upper surface of the base portion of the heat dissipating member is bonded to a lower surface of the supporting member.