Abstract: Systems and methods are provided for a remotely-deployed, automated, computer network diagnostic tool. Methods may include deploying a diagnostic script from a central network node to multiple network endpoints via an automated network agent tool, and running the diagnostic script on each of the multiple endpoints. Running the script on each endpoint may include compiling a set of URLs, compiling a set of proxy servers, testing a plurality of network paths, and generating a set of diagnostic data for each endpoint. Diagnostic data may include a success status, a latency performance score, and a response size measurement. Methods may include collating the sets of diagnostic data, generated from the multiple endpoints, into a collated set of diagnostic data. Methods may include analyzing the collated set of diagnostic data, via a big-data analysis tool, based on a set of performance metrics.

Abstract: An optical device such as an optical fiber waveguide having at least one light transceiving end suitable for transmitting or receiving light, the optical device comprising a core suitable for allowing transmission therethrough of light, a cladding layer surrounding the core and having an index of refraction less than that of the core, and an embedded lens integrally located at the light transceiving end. The embedded lens is preferably a gradient refractive index (GRIN) lens having a refractive index that varies along a radial axis of the light transceiving end of the device and along a longitudinal axis of the light transceiving end of the device. The embedded GRIN lens is comprised of a plurality of dopant regions; the dopant regions comprise regions extending a predetermined distance along the longitudinal axis and having a predetermined diameter.

Abstract: A technique is provided for manually performing a soldering operation on an article with a low-solids flux-containing solder to bond an object to the article with a reduced amount of flux residues. The technique is practiced by first manually applying heat to the article and to the object which is in contact therewith, such as by contacting the article and/or object with a heated tip of a soldering pencil, iron or gun. Once the object and article have been heated, a low-solids flux-containing solder is then applied so as to be reflowed upon contact with the heated article and the object in order to bond them together when the solder solidifies. Simultaneously, heated air (i,e., air heated above the ambient temperature) is directed at the article and the object towards the region where the solder is being applied to maintain any flux vapors, which were created upon heating of the solder, in their vaporous state.

Abstract: An component or connector lead (12) is soldered to a bare copper metallized area (14) on a circuit board (16) using core solder (26) by manually applying heat from a heated tip (24) to a separate one of the lead and metallized area. As the heat is being applied, a vacuum is drawn in the region where the solder is applied to the lead and/or metallized area to draw off any flux vapors created upon heating of the solder. At the same time, hot air is also directed into the region where the solder is being applied to maintain the flux vapors, created upon heating of the solder, in their vaporous state to facilitate such vapors being drawn off, thereby reducing the amount of flux residues resulting from the soldering operation.

Abstract: In a flame hydrolysis method for depositing glass soot used ultimately to make optical fiber, a reactant that forms the glassy soot stream is delivered to the torch (20) in liquid form and an ultrasonic nozzle (34) in the torch atomizes the reactant or breaks the reactant into a fine mist without the use of a gas.

Abstract: A fluorine-doped silica soot cylinder (11) is consolidated by containing it within an encapsulation structure (29) within a furance (21). The atmosphere within the encapsulation structure is kept substantially stagnant during the consolidating, and the volume enclosed by the encapsulation structure (29) is only slightly greater than the volume of the soot cylinder (11). A gap (52) between the volume enclosed by the encapsulating structure and the furnace is kept small enough to impede gas flow to a sufficient extent that the atmosphere within the encapsulating structure (29) is substantially stagnant during consolidation. During consolidation, fluorine concentration within the encapsulation structure (29) is uniformly distributed within the soot cylinder (11).

Abstract: A fluorine-doped silica soot cylinder (11) is consolidated by containing it within an encapsulation structure (29) within a furnace (21). The atmosphere within the encapsulation structure is kept substantially stagnant during the consolidating, and the volume enclosed by the encapsulation structure (29) is only slightly greater than the volume of the soot cylinder (11). A gap (52) between the volume enclosed by the encapsulating structure and the furnace is kept small enough to impede gas flow to a sufficient extent that the atmosphere within the encapsulating structure (29) is substantially stagnant during consolidation. During consolidation, fluorine concentration within the encapsulation structure (29) is uniformly distributed within the soot cylinder (11).

Abstract: A glass soot deposition torch (30; FIG. 2) having gas passages arranged to provide an inner (34) and outer (36) flame front is disclosed in which the temperature of the inner front is higher than the outer front. A passage is located within the outer front (36) through which glass soot (32) is directed onto the surface of a growing soot-form core (38).