| Class / Patent application number | Description | Number of patent applications / Date published |
|---|
| 065406000 | Joining or bonding optical fibers, waveguides, or preforms (e.g., coupling, etc.) | 27 |
| 20080282742 | DEVICES AND METHODS FOR SIDE-COUPLING OPTICAL FIBERS TO OPTOELECTRONIC COMPONENTS - Optical devices, components and methods for mounting optical fibers and for side-coupling light to/from optical fibers using a modified silicon V-groove, or silicon V-groove array, wherein V-grooves, which are designed for precisely aligning/spacing optical fibers, are “recessed” below the surface of the silicon. Optical fibers can be recessed below the surface of the silicon substrate such that a precisely controlled portion of the cladding layer extending above the silicon surface can be removed (lapped). With the cladding layer removed, the separation between the fiber core(s) and optoelectronic device(s) can be reduced resulting in improved optical coupling when the optical fiber silicon array is connected to, e.g., a VCSEL array. | 11-20-2008 |
| 20110265521 | METHOD FOR ASSEMBLING OPTICAL CONNECTOR - An optical connector assembling method capable of preventing workability from worsening is provided. First, when assembling the optical connector, an optical cord ( | 11-03-2011 |
| 20120159996 | Curved sensor formed from silicon fibers - Methods and apparatus for fabricating a curved sensor from silicon fibers are disclosed. In another embodiment, a curved sensor is produced having mini-sensors of differing sizes. In another embodiment, these mini-sensors are configured so that every other mini-sensor in a row of mini-sensors is shifted upwards slightly relative to its neighboring mini-sensors in the same row. | 06-28-2012 |
| 20130219970 | MICROBUBBLE OPTICAL RESONATOR - An optical microresonator is configured as an optical microbubble formed along a section of an optical microcapillary. The curvature of the outer surface of the microbubble creates an optical resonator with a geometry that encourages the circulating WGMs to remain confined in the central region of the bubble, creating a high Q optical resonator. The resonator may be tuned by modifying the physical properties of the microbubble, allowing the resonator to be used as an optical filter. The resonator may also be used as a sensor or laser by introducing the material to be sensed (or the active laser material) into the microcapillary along which the microbubble is formed. | 08-29-2013 |
| 065407000 | End to end (i.e., butt end joining) | 8 |
| 20080276651 | Increasing the cladding-to-core ratio (D/d) of low D/d ratio core rods in optical fiber performs - An optical fiber preform is fabricated by inserting a number of core body pieces end-to-end inside a glass cylinder, wherein the pieces may have a cladding-to-core diameter (D/d) ratio within the range of one to four. The cylinder with the inserted core body pieces is mounted vertically on a furnace and heated so that the cylinder becomes elongated and its outside diameter collapses to form a core rod from which core rod sections with D/d ratios greater than five, can be cut. A soot overcladding is deposited on the circumference of a core rod section until the diameter of the deposited soot builds to a determined value. The core rod section with the deposited soot overcladding is consolidated to obtain a finished optical fiber preform. The preform preferably has a D/d ratio of about 15 or more, and an optical fiber may be drawn directly from the preform. | 11-13-2008 |
| 20110056246 | OPTICAL CONNECTOR ASSEMBLING JIG AND OPTICAL CONNECTOR ASSEMBLING METHOD - An optical connector assembling jig and an optical connector assembling method includes an optical connection. The optical connector assembling jig includes a base and a guide. The base is provided in a longitudinal direction with an accommodation groove for accommodating an optical fiber, and a rear pressing member for restraining a rear part of the optical fiber accommodated in the accommodation groove. The rear part is set apart from an embedded fiber. The guide has a front holding portion for holding a front part of the optical fiber accommodated in the accommodation groove. The front part is near the embedded fiber, and the guide is capable of moving in the longitudinal direction. Moving the base toward the optical connector causes the intermediate section of the optical fiber to separate from the accommodation groove and bend. By moving the base further toward the optical connector, a buffered fiber in the optical fiber can be connected to the embedded fiber. | 03-10-2011 |
| 20110088434 | APPARATUS FOR MECHANICALLY SPLICING OPTIC FIBERS - Apparatus for mechanically splicing two optic fibers, including an inner section including scoring apparatus, cleaving channels and a splicing channel; and two optic fiber restraining members, each being in operative communication with, and movable with respect to, the inner section; wherein restraining members locate end sections of optic fiber cores of said optic fibers in respective cleaving channels for scoring by said scoring apparatus; and wherein relative movement of the restraining members away from the inner section cleaves said end sections of optic fiber cores; and further relative movement between the restraining members and the inner section located cleaved end sections of said optic fiber cores into respective openings of the splicing channel to effect mechanical splicing therebetween. | 04-21-2011 |
| 20110226019 | Automatic core-alignment for fusion splicing double-clad fibers - In aligning ends of optical fibers, e.g. ends of large mode area double-clad fibers (LMA-DCFs), in a fiber optic fusion splicer the best position of the object plane of the optical system for observing images of the cores of the fiber ends are first determined by maximizing the contrast of the core image, in particular the core image peak in intensity profiles. The alignment process may be performed by adjusting the offset distance between the observed cores in some suitable way, e.g. by using a cascade technique. In e.g. a process for prealigning the fiber ends the self-focusing effect of optical fibers can be used to first determine the best object plane position for observing the self-focusing effect and then the very pre-alignment operation can be performed. This may extend the range of image analysis allowing e.g. that alignment, in particular core alignment, can be performed without requiring direct information showing the position of sides or edges of the claddings in captured pictures. | 09-22-2011 |
| 20140102148 | System and Method for Splicing Optical Fibers in Order to Mitigate Polarization Dependent Splice Loss - In certain embodiment, a fiber fusion apparatus for mitigating polarization dependent splice loss include a first fiber guide operable to maintain alignment of a first optical fiber relative to a center axis and a second fiber guide operable to maintain alignment of a second optical fiber relative to the center axis. The apparatus further includes three or more electrodes evenly-spaced around the center axis. Each of the three or more electrodes is operable to apply heat to adjacent ends of the first and second optical fibers in order to fuse the first and second optical fibers. | 04-17-2014 |
| 20150059412 | OPTICAL FIBER RIBBONIZATION APPARATUS AND METHOD - Method of ribbonizing a plurality of optical fibers ( | 03-05-2015 |
| 20160011378 | OPTICAL FIBER SPLICING TOOL AND OPTICAL FIBER SPLICING METHOD | 01-14-2016 |
| 20160154181 | APPARATUS AND METHOD FOR SPLICING ALL-DIELECTRIC SELF-SUPPORTING FIBER OPTIC CABLE | 06-02-2016 |
| 065408000 | Side to side | 5 |
| 20110132038 | Soot Pressing for Optical Fiber Overcladding - A method and an apparatus for making an optical fiber preform comprising the steps of (i) depositing a plurality of rods are deposited into an inner cavity of an apparatus; (ii) depositing particulate glass material in the inner cavity between the rods and the inner wall; and (iii) applying pressure against the particulate glass material to pressurize the particulate glass material against the plurality of rods. | 06-09-2011 |
| 065409000 | Having plural adjacent fibers or rods sheathed (i.e., bundle) in tube or enclosure | 4 |
| 20120144869 | GLASS OPTICAL WAVEGUIDES INCORPORATING MATERIALS OF INTEREST AND METHODS OF FABRICATING THE SAME - A method of incorporating within a glass optical waveguide a material of interest having a property of interest that would be neutralized by exposure to molten glass includes combining pieces of a light-transmissive first glass with the material of interest. The combined first glass and material of interest are shaped within a container and heated to a temperature sufficiently high to cause the glass pieces and material of interest to mutually coalesce and form a light-transmissive core rod, but not high enough that the first glass melts and neutralizes the property of interest. A cladding tube is heated and fused about the core rod to define a mono rod. An optical waveguide through which light propagates by internal reflection, and which incorporates the material of interest, is defined when the cladding tube comprises a glass that renders the cladding of lower refractive index than the core rod. | 06-14-2012 |
| 20130291603 | OPTICAL FIBER ARTICLE FOR HANDLING HIGHER POWER AND METHOD OF FABRICATING OR USING - An optical fiber preform, and method for fabricating, having a first core, a second core spaced from the first core and first and second regions, the first region having an outer perimeter having a first substantially straight length and the second region having an outer perimeter having a second substantially straight length facing the first straight length. One of the regions can comprise the first core and the other comprises the second core. The preform can be drawn with rotation to provide a fiber wherein a first core of the fiber is multimode at a selected wavelength of operation and a second core of the fiber is spaced from and winds around the first core and has a selected longitudinal pitch. The second core of the fiber can couple to a higher order mode of the first core and increase the attenuation thereof relative to the fundamental mode of the first core. | 11-07-2013 |
| 20140216109 | METHOD OF MANUFACTURING PREFORM FOR MULTICORE FIBER AND METHOD OF MANUFACTURING MULTICORE FIBER - A plurality of clad rods, and a clad tube, an arrangement process for arranging the plurality of core rods and the plurality of clad rods in a tube of the clad tube, in a state in which distances between center axes of the adjacent core rods become equal to each other and a state in which parts of outer circumferential surfaces in the adjacent rods contact, and an integration process for integrating the clad tube and the plurality of core rods and the plurality of clad rods arranged in the tube, wherein a ratio of a total cross-sectional area of a direction orthogonal to a length direction in the plurality of core rods and the plurality of clad rods with respect to an internal cross-sectional area of the tube of a direction orthogonal to a length direction in the clad tube is 0.84 or more. | 08-07-2014 |
| 20160075590 | PRODUCTION METHOD OF OPTICAL FIBER PREFORM, AND PRODUCTION METHOD OF OPTICAL FIBER - A production method of an optical fiber preform includes first preparing a first preform having a plurality of glass preforms and a first cladding portion disposed between the plurality of glass preforms, and first arranging a second cladding portion to surround the first preform. At the first arranging, a material gas and a combustion gas are ejected from a burner to produce glass particles. The first preform and the burner are moved relative to each other in a longitudinal direction of the first preform. The glass particles are deposited on the first preform. | 03-17-2016 |
| 065412000 | Rod placed inside of tube | 10 |
| 20090031758 | Telecommunications Cable Jacket Adapted for Post-Extrusion Insertion of Optical Fiber and Methods for Manufacturing the Same - The present disclosure relates to a telecommunications cable having a jacket including a feature for allowing post-extrusion insertion of an optical fiber or other signal-transmitting member. The present disclosure also relates to a method for making a telecommunications cable having a jacket including a feature for allowing post-extrusion insertion of an optical fiber or other signal-transmitting member. | 02-05-2009 |
| 20090272152 | METHOD FOR MANUFACTURING OPTICAL FIBER - The present invention provides a method for manufacturing an optical fiber comprising the steps of forming a glass body containing a core, preparing a glass tube which will form a cladding portion, inserting the glass body into the glass tube, and collapsing the glass tube with the glass body by heating, wherein the method comprises a step of processing the glass tube such that it has at least one end tapered to which a pull is to be applied. The method may further comprise the steps of cleaning the outer surface of the glass tube, choosing the outer diameter of the glass body and the inner diameter of the glass tube such that the difference between the two diameters is not lower than 1.0 mm but not higher than 10.0 mm, choosing the inner diameter of a supporting tube attached to an inert end (opposite to the pulled end) of the glass tube such that it is equal to or higher than the diameter of the glass tube, with respect to the drawn end of the glass tube, processing the end such that its inner surface has a taper and the tapered end is sealed, and providing a spacer to the glass assembly such that the interval between the outer surface of the glass body and the inner surface of the glass tube exhibits a practically uniform profile over the full length of the glass assembly. | 11-05-2009 |
| 20100326139 | OPTICAL FIBER PREFORM MANUFACTURING METHOD - An optical fiber preform manufacturing method includes: supporting a drilling jig in a radial direction of a preform that is cylinder-shaped; moving the drilling jig in a longitudinal direction of the preform; and forming a plurality of slits each extending in the longitudinal direction and each directed from an outer side of the preform toward a center the preform, and a plurality of holes each extending in the longitudinal direction and each connecting with an end of one of the plurality of slits in a depth direction of the one of the plurality of slits. | 12-30-2010 |
| 20110100063 | Methods For Forming An Overclad Portion Of An Optical Fiber From Pelletized Glass Soot - Methods of forming an overclad portion of an optical fiber are described which include positioning a core cane member in an overclad tube to form a rod and tube assembly. Thereafter, glass soot pellets are positioned in the rod and tube assembly between the core cane member and an interior sidewall of the overclad tube. The rod and tube assembly is then redrawn under conditions effective to form the overclad tube and the glass soot pellets into a continuous, void-free glass layer surrounding the core cane member at a sintering time t | 05-05-2011 |
| 20120073330 | OPTICAL FIBER END PROCESSING METHOD AND OPTICAL FIBER END PROCESSING APPARATUS - An optical fiber end processing method includes the steps of: an optical fiber fixing step of fixing two parts of the optical fiber; a first heating step of heating a tip end side part of the optical fiber between two fixed parts fixed in the optical fiber fixing step, and melting the optical fiber of the tip end side heating part; a second heating step of heating a part on a base end side of the optical fiber between the fixed parts away from the tip end side heating part in a state that two parts of the optical fiber are fixed, and making the holes of the optical fiber disappear; and a removing step of removing the tip end side heating part after the second heating step. | 03-29-2012 |
| 20120186303 | OPTICAL FIBER AND METHOD OF MANUFACTURING OPTICAL FIBER PREFORM - A method for manufacturing an optical fiber preform that includes preparing a glass cylinder with inner and outer surfaces forming at least part of a cladding portion are repeatedly polished, and a glass core rod that includes a core portion having a higher refractive index than the cladding portion; and inserting the core rod into the glass cylinder and heating the glass cylinder and core rod to form a single body. The repeated polishing of the inner surface of the glass cylinder includes passing pure water that does not contain a cutting fluid over the inner surface for at least the final polishing. The polishing is preferably performed using a polishing cloth to which are affixed diamond abrasive grains. The glass core rod and the glass cylinder are preferably formed of composite quartz glass. | 07-26-2012 |
| 20130283863 | METHOD OF FUSING AND STRETCHING A LARGE DIAMETER OPTICAL WAVEGUIDE - Methods for making a preform for a large diameter optical waveguide such as a cane waveguide are disclosed. The method includes inserting a preform into a glass tube to serve as cladding that provides a thickened preform, simultaneously fusing and stretching the thickened preform, sectioning the stretched and still thickened preform and repeating the procedure if necessary to provide an even further thickened preform. The drawing apparatus can be configured to work with the preform disposed either horizontally or vertically and usually includes a graphite resistance furnace. Typically, the drawing apparatus is an upper portion of a draw tower used for drawing an optical fiber from an optical fiber preform. The draw tower includes a tractor pulling mechanism that can adjust to grip a wide range of diameters. | 10-31-2013 |
| 20130291604 | METHOD OF MANUFACTURING AN OPTICAL FIBRE GLASS PREFORM - A method of manufacturing an optical fibre preform includes: producing a core rod having a core rod diameter; inserting the core rod into a glass fluorine-doped intermediate cladding tube so as to form a core assembly, the intermediate cladding tube having an inner diameter and an outer diameter, wherein the inner diameter is larger than the core rod diameter, the radial difference between the inner diameter and the core rod diameter defining an annular gap; and applying a negative pressure inside the annular gap; and forming a core preform by heating the core assembly to collapse the intermediate cladding tube around the core rod while maintaining the negative pressure, wherein heating includes moving a heater outside the intermediate cladding tube and along an axial direction of the same, and forming an overcladding region surrounding the core preform so as to form an optical fibre preform. | 11-07-2013 |
| 20140174134 | SYSTEM AND METHOD FOR FABRICATING OPTICAL FIBER PREFORM AND OPTICAL FIBER - A method of manufacturing an optical fiber preform or an optical fiber is provided. The method includes the steps of: (a) providing a glass tube and a glass core rod; (b) inserting the glass core rod into the glass tube to form an assembled body; (c) heating the assembled body to cause the glass tube to collapse on and adhere to the glass core rod; and (d) treating an interface gap between the glass core rod and the glass tube during heating of at least a portion of the assembled body. Treating of the interface gap involves: (i) establishing a vacuum pressure in the interface gap, (ii) increasing a pressure of the interface gap by a treatment gas through the interface gap for a predetermined time, and (iii) re-establishing a vacuum pressure in the interface gap after the predetermined time has elapsed. | 06-26-2014 |
| 20150307387 | METHOD FOR FORMING OPTICAL FIBER AND PREFORMS - A method of forming an optical fiber includes the steps of forming a silica-based soot blank with at least one silica-based soot core cane at least partially embedded in the soot blank. The soot blank with the soot core cane positioned therein is consolidated to form a preform. The preform is then drawn to form an optical fiber. The soot core cane preferably has an average bulk density within 10% of the bulk density of the soot blank, and more preferably within 5% of the bulk density of the soot blank. | 10-29-2015 |
