Abstract: An optical subassembly package configuration for monitoring a fiber, the configuration includes a container, an optical subassembly, an optical fiber, and a ferrule. The container has a face, and the optical subassembly is disposed within the container. The optical fiber communicates with the subassembly. The ferrule is attached to the face of the container, the fiber being monitored terminates inside the ferrule.

Abstract: An optical subassembly package configuration for monitoring a fiber, the configuration includes a container, an optical subassembly, an optical fiber, and a ferrule. The container has a face, and the optical subassembly is disposed within the container. The optical fiber communicates with the subassembly. The ferrule is attached to the face of the container, the fiber being monitored terminates inside the ferrule.

Abstract: The subassembly includes a laser for emitting signals towards fibers to be monitored, a passive alignment carrier, a photodetector for monitoring reflected laser signals from the fibers and for monitoring laser output power, and an optical fiber. The laser is disposed within the passive alignment carrier. The optical fiber is embedded in the passive alignment carrier, and has an angled fiber facet. The laser emits signals toward and through the angled fiber facet, whereby a portion of the laser signal illuminates the photodetector, and another portion illuminates the fibers that are being monitored and reflects back to the photodetector such that faults on the fibers can be detected.

Abstract: The subassembly includes a laser for emitting signals towards fibers to be monitored, a passive alignment carrier, a photodetector for monitoring reflected laser signals from the fibers and for monitoring laser output power, and an optical fiber. The laser is disposed within the passive alignment carrier. The optical fiber is embedded in the passive alignment carrier, and has an angled fiber facet. The laser emits signals toward and through the angled fiber facet, whereby a portion of the laser signal illuminates the photodetector, and another portion illuminates the fibers that are being monitored and reflects back to the photodetector such that faults on the fibers can be detected.

Abstract: The subassembly includes a laser for emitting signals towards fibers to be monitored, a passive alignment carrier, a first photodetector for monitoring reflected laser signals from the fibers, a second photodetector for monitoring laser output power, and an optical fiber. The laser is disposed within the passive alignment carrier. The optical fiber is embedded in the passive alignment carrier, and has an angled fiber facet. The laser emits signals toward and through the angled fiber facet, whereby a portion of the laser signal illuminates the second photodetector, and another portion illuminates the fibers that are being monitored and reflects back to the first photodetector such that faults on the fibers can be detected.

Abstract: The subassembly includes a laser for emitting signals towards fibers to be monitored, a first photodetector for monitoring reflected laser signals from the fibers, a second photodetector for monitoring laser output power, and an optical fiber. The optical fiber has an angled fiber facet. The laser emits signals toward and through the angled fiber facet, whereby a portion of the laser signal illuminates the second photodetector, and another portion illuminates the fibers that are being monitored and reflects back to the first photodetector such that faults on the fibers can be detected.

Abstract: An apparatus and a method for aligning an optical fiber with an optoelectronic device inside an optoelectronic package using an internal automated micro-aligner and internal solder heater means for locking the optical fiber in a precisely aligned position with the optoelectronic device.

Abstract: An optoelectronic module is disclosed in which an optoelectronic device is precisely aligned with an optical fiber. The optoelectronic module comprises a first member, a second member for supporting an end of the optical fiber in a fixed position relative the first member along an axis, and a third member for mounting at least one optoelectronic device. A plurality of positioning members are adjustably positioned on the first member for supporting the third member to maintain aligned relation of the optoelectronic device with the axis.

Abstract: An optoelectronic package includes an optical fiber cable assembly and feedthrough assembly which provide high performance and high reliability optical fiber alignment, locking and sealing. An optical fiber is fed through a nose tube into the package. The fiber is selectively metallized at its end. A solder lock joint on a substrate on the package floor preferably of an SnAg- based or SnSb- based solder. It surrounds at least part of the metallized portion of the fiber so as to hold the fiber in its desired position, in alignment with an optoelectronic device in the package. With Sn metallization on the fiber, this results in a highly reliable solder lock joint. A solder seal joint forms a hermetic seal between the nose tube and the Au metallized fiber. This solder is preferably 80Au20Sn. A rigid cylindrical seal tube sleeve insert on the fiber is designed to guide the fiber into the nose tube without bending or damaging the fiber.

Abstract: A spectrograph usable as a demultiplexer/detector in a wavelength division multiplexing optical system. The spectrograph comprises a planar waveguide and a detector array. The planar waveguide has a dispersive edge having an inwardly concave shape, an input edge, and a straight output edge. The dispersive edge has a reflective diffraction grating formed on it, the grating having a variable line spacing. An optical input signal comprising a plurality of different wavelength ranges enters the waveguide at the input edge, and travels through the waveguide and strikes the grating. The grating focuses the optical energy in each of the wavelength ranges at a focal spot at the output edge, the position of each focal spot being a function of wavelength. The detector array comprises a plurality of photodetectors positioned along a straight line, such that the photodetectors are positioned at the focal spots. Each photodetector therefore detects the optical energy in one of the input ranges.

Abstract: A method is provided for epitaxially growing single crystalline silicon on a silicon substrate (10) from a silicon-bearing gas (26) at a temperature below the pyrolytic threshold of the gas and at temperatures below those normally required for epitaxial growth. An oxidized silicon substrate (10) is fluorinated (equation 2, FIG. 2) to replace the silicon-oxide layer with an adsorbed fluorinated layer. The substrate is placed in a laser photo-CVD reactor chamber (20), the chamber is evacuated to a sub-UHV level of 10.sup.-3 to 10.sup.-7 Torr, the substrate is heated to 570.degree. C., hydrogen gas (24) is introduced into the chamber, and excimer pulsed ultraviolet laser radiation (32 from laser 12) is applied through the hydrogen gas to impinge the wafer substrate.

Abstract: An apparatus for repairing both clear and opaque defects in a photomask having a metal film pattern on a glass plate in which a visible laser light source is pulsed at selected frequencies to direct an optically focused laser beam into a gas sealed cell containing a mask. At one frequency, the laser pulses ablate opaque mask defects. At another frequency, and with the cell filled with a metal bearing gas, the laser beam causes thermal decomposition of the gas and deposition of metal to cure clear defects.

Abstract: A method for depositing a micron-size metallic film on a transparent substrate by thermal deposition employing a focused visible laser. The method includes the step of positioning the substrate in a gas cell containing a metal bearing gaseous compound. A nucleation layer is formed on a surface of the substrate by either shining an ultraviolet light on the substrate surface or by heating the substrate to a temperature which is less than the temperature at which the molecules of the gaseous compound decompose. Next, a laser which may be visible or near infrared is focused onto the substrate to provide localized heating of the area of the substrate to which the beam is incident. Molecules of the gaseous compound thermally decompose on the heated area to deposit a metal film thereon.

Abstract: A method for repairing clear defects on a photomask. The method includes the steps of coating the photomask with a positive photoresist; exposing the photoresist to a laser beam for localized heating thereof to a temperature above 500.degree. C. to darken or char the polymer; and removing the unexposed polymer from the photomask. The method may also include the intermediate step of heating the polymer to a temperature between 200.degree. C. and 500.degree. C. to brown the polymer before the polymer is exposed to the laser which heats it to a temperature above 500.degree. C.

Abstract: A method for depositing a micron-size metallic film on a transparent substrate by thermal deposition employing a focused visible laser. The method includes the step of positioning the substrate in a gas cell containing a metal bearing gaseous compound. A nucleation layer is formed on a surface of the substrate by either shining an ultraviolet light on the substrate surface or by heating the substrate to a temperature which is less than the temperature at which the molecules of the gaseous compound decompose. Next, a laser which may be visible or near infrared is focused onto the substrate to provide localized heating of the area of the substrate to which the beam is incident. Molecules of the gaseous compound thermally decompose on the heated area to deposit a metal film thereon.

Abstract: An electrochemical system including a chlorine positive electrode, such as zinc-chlorine cell, is disclosed which complexes chlorine by utilizing (1) a selected organic compound, such as, for example, n-butyl carbamate, which includes a --NH.sub.n R.sub.2-n functionality wherein R is an appropriate organic moiety, and n is an integer, either 1 or 2, and an electron-withdrawing substituent alpha to the nitrogen and (2) a buffer to provide a liquid oil, which yields chlorine when required in discharge of the cell.