Patent application number | Description | Published |
20080273839 | Connectorized nano-engineered optical fibers and methods of forming same - Connectorized nano-engineered optical fibers and method for forming them are disclosed. The methods include heating a mid-span bare fiber portion of the nano-engineered fiber to collapse the airlines therein so as to form an airline-free portion. The fiber is then inserted into a ferrule channel so that the fiber end protrudes beyond the ferrule end face, but with the airline-free portion positioned at the ferrule end face. The fiber is then cleaved at or near the ferrule end face in the airline-free portion, and the new fiber end face polished to create a solid fiber end face that coincides with the ferrule end face. The methods result in at most only minimal changes to the mode field diameter (MFD) and/or to the outer cladding diameter, which is essential in forming a connectorized nano-engineered fiber that can connect to like-size nano-engineered or non-nano-engineered fibers. | 11-06-2008 |
20080304796 | Connectorized nano-engineered optical fibers and methods of forming same - Connectorized nano-engineered optical fibers and method for forming them are disclosed. The methods include heating a mid-span bare fiber portion of the nano-engineered fiber to substantially collapse the airlines therein so as to form a substantially airline-free portion. The fiber is then inserted into a ferrule channel so that the fiber end protrudes beyond the ferrule end face, but with the substantially airline-free portion positioned at the ferrule end face. The fiber is then cleaved at or near the ferrule end face in the substantially airline-free portion, and the new fiber end face polished to create a solid fiber end face that coincides with the ferrule end face. The methods result in relatively small changes to the mode field diameter (MFD) and/or to the outer cladding diameter. | 12-11-2008 |
20090199597 | Systems and methods for collapsing air lines in nanostructured optical fibers - Systems and methods of collapsing the air lines in the air line-containing region of a nanostructure optical fiber are disclosed. One method includes initiating irradiation of a portion of the nanostructure optical fiber from essentially opposite directions with at least first and second laser beams having substantially equal power and essentially the same mid-infrared wavelength. The method includes continuing the irradiation for an irradiation time t | 08-13-2009 |
20100054679 | Fiber optic cable assembly with floating tap - A fiber optic cable assembly with a floating tap is disclosed, wherein the assembly comprises a fiber optic cable having a cable fiber assembly, such as in the form of a ribbon stack. The assembly includes at least one network access point (NAP) for accessing at least one cable fiber in the cable fiber assembly and at least one strength area for example a strength member. At least one cable fiber is extracted from the cable fiber assembly and held by a transition assembly. A buffer conduit loosely contains the at least one cable fiber and guides it to an intermediate buffer conduit, which in turn guides the at least one cable fiber to a splice tube. The intermediate buffer conduit can translate relative to the splice tube. At least one tether fiber is spliced to the at least one cable fiber. Alternatively, the at least one cable fiber has sufficient length to serve as the at least one tether fiber so that splicing to another fiber is not required. Each strength member is covered by a movable member. A bonding structure bonds the cable fiber assembly, buffer conduit and movable member so that the cable fiber assembly can translate but not rotate relative to the cable within the NAP. This allows the tap point to “float” within the NAP when the cable fiber assembly needs to translate within the cable. | 03-04-2010 |
20100154609 | Tools and Methods for Manufacturing Fiber Optic Distribution Cables - Fiber optic distribution cables and methods for manufacturing the same are disclosed. The methods present one or more optical fibers outward of the protective covering for distribution of the same toward the subscriber. Specifically, the methods include presenting a length of distribution optical fiber outward of the protective covering that is longer than the opening at access location. After the opening is made in the protective covering at the access location, the optical fibers for distribution are selected. Then a tool according to the present invention is positioned about the optical fibers selected for distribution and slid within the protective covering of the fiber optic distribution cable until it reaches a cutting location within the fiber optic distribution cable. Consequently, the tool is positioned for cutting the distribution optical fiber at a cutting location within the fiber optic distribution cable at a downstream location. Thereafter, the tool is removed and the cut distribution optical fiber is routed through the opening at the access location so the distribution optical fiber is presented outside the protective covering. | 06-24-2010 |
20100278495 | FIBER OPTIC CABLE ASSEMBLY WITH FLOATING TAP - A fiber optic cable assembly with a floating tap is disclosed, wherein the assembly comprises a fiber optic cable having a cable fiber assembly, such as in the form of a ribbon stack. The assembly includes at least one network access point (NAP) for accessing at least one cable fiber in the cable fiber assembly and at least one strength area for example a strength member. At least one cable fiber is extracted from the cable fiber assembly and held by a transition assembly. A buffer conduit loosely contains the at least one cable fiber and guides it to an intermediate buffer conduit, which in turn guides the at least one cable fiber to a splice tube. The intermediate buffer conduit can translate relative to the splice tube. At least one tether fiber is spliced to the at least one cable fiber. Alternatively, the at least one cable fiber has sufficient length to serve as the at least one tether fiber so that splicing to another fiber is not required. Each strength member is covered by a movable member. A bonding structure bonds the cable fiber assembly, buffer conduit and movable member so that the cable fiber assembly can translate but not rotate relative to the cable within the NAP. This allows the tap point to “float” within the NAP when the cable fiber assembly needs to translate within the cable. | 11-04-2010 |
20110198324 | METHODS FOR LASER PROCESSING ARRAYED OPTICAL FIBERS ALONG WITH SPLICING CONNECTORS - A method for laser processing arrays of optical fibers and high-fiber count splicing connectors and adapters are disclosed. The method includes the steps of providing a structure having optical fibers arranged in a plurality of rows and placing a protection element adjacent to a first row of optical fibers and a second row of optical fibers. Thereafter, the first row of optical fibers can be processed using the laser. The protection element may also be used to move optical fibers. In one embodiment, the protection element has a first portion and a second portion that have relative movement therebetween. In other variations, an absorption element may be provided adjacent the first row of optical fibers for inhibiting incidental damage to the structure. | 08-18-2011 |
20110229083 | FIBER OPTIC INTERFACE WITH TRANSLATABLE FERRULE DEVICE - Optical fiber ferrules ( | 09-22-2011 |
20110229088 | FIBER OPTIC INTERFACE DEVICE WITH POSITIONABLE CLEANING COVER - A fiber optic interface device ( | 09-22-2011 |
20110229089 | SMALL-FORM-FACTOR FIBER OPTIC INTERFACE ASSEMBLIES FOR ELECTRONIC DEVICES - Small-form-factor fiber optic interface assemblies ( | 09-22-2011 |
20110229090 | FIBER OPTIC INTERFACE DEVICES FOR ELECTRONIC DEVICES - Fiber optic interface devices ( | 09-22-2011 |
20110262076 | FIBER OPTIC ASSEMBLIES HAVING CONNECTORS WITH RECESSED OPTICAL FIBERS - Fiber optic assemblies including a plurality of optical fibers in a connector having a ferrule are disclosed. The ferrule has a front end face and a plurality of bores with the plurality of optical fibers being disposed within one of the respective plurality of bores. The fiber optic assemblies have the plurality of optical fibers recessed from the front end face of the ferrule by a suitable distance to inhibit physical contact of the plurality of optical fibers when mated with a complementary connection. Consequently, the fiber optic assemblies are suited for hundreds or thousands of connections and disconnections (i.e., mating cycles) with reduced susceptibility from damage and/or optical attenuation caused by dirt, debris and the like as expected with the consumer electronic/device environments. | 10-27-2011 |
20120018481 | COMMERCIAL PACKAGING OF DISPOSABLE CLEAVER - A method of cleaving an optical fiber using a disposable abrasive film is disclosed. The method includes preparing an end of an optical fiber by exposing a length of the optical fiber. The exposed optical fiber is brought into contact with a tangential swipe formed of abrasive film to cause the optical fiber to cleave substantially at the location of contact leaving an optical fiber stub with a cleaved end. The optical fiber stub is polished with a polishing film having a coarse grit and may be polished a second time with a polishing film having a fine grit. | 01-26-2012 |
20120155803 | FERRULE ASSEMBLIES, CONNECTOR ASSEMBLIES, AND OPTICAL COUPLINGS HAVING CODED MAGNETIC ARRAYS - Ferrule assemblies having at least one coded magnetic array are disclosed. In one embodiment, a ferrule assembly includes a ferrule body having a coupling surface and a coded magnetic array having a plurality of magnetic regions. The coded magnetic array may be located within the coupling surface. The ferrule assembly further includes a lens component located within the ferrule body. The lens component may have a facet at the coupling surface of the ferrule body at a predetermined angle. In another embodiment, a translating ferrule assembly includes an optical interface and a coded magnetic array, and is configured to translate within a connector housing of an optical connector when coupled to an electronics device. Optical couplings having a coded magnetic array and sockets for receiving a connector are also disclosed. | 06-21-2012 |
20120163754 | OPTICAL COUPLINGS HAVING CODED MAGNETIC ARRAYS AND DEVICES INCORPORATING THE SAME - Optical couplings for making and optical connection between one or more devices are disclosed. In one embodiment, an optical coupling includes a coupling face, an optical interface within the coupling face, an optical component positioned within the optical interface, and at least one coded magnetic array. The at least one coded magnetic array may include a plurality of magnetic regions configured aid in mating the optical component with a corresponding optical component of a complementary mated optical coupling to a predetermined tolerance for optical communication. Optical cable assemblies and electronics devices having optical couplings with optical interfaces using coded magnetic arrays are also disclosed. | 06-28-2012 |
20120204379 | NOZZLE-BASED AEROSOL CLEANER FOR OPTICAL CONNECTORS - A system for cleaning internal optical components of a fiber optic connector includes a source of cleaning medium such as compressed air connected to a cleaning tip. The cleaning tip has a body and a tongue that is configured to be inserted into the end of the fiber optic connector. Nozzles are formed on the tongue. The tongue may have features to open shutters and/or other protective features in the connector that normally protect the internal optical components. When the tongue is inserted into the end of the connector, the nozzles are positioned adjacent optical components to be cleaned and compressed air is delivered through the nozzles to clean the components. Backwash can be exhausted around the tongue or through the tongue to eject contaminants from the fiber optic connector. | 08-16-2012 |
20120216829 | MICRO FILAMENT CLEANING TOOL FOR EMERGING OPTICAL CONNECTORS - A cleaning tool for cleaning internal optical components of a fiber optic connector includes a cleaning strip that is advanced past one or more optical surfaces of the connector to wipe the connector free of contaminants. The cleaning tool includes a drive mechanism that is operated by rotating a drive, thereby advancing the cleaning strip along a cleaning strip path and into contact with the one or more optical surfaces. The cleaning tool comprises a cleaning tip that functions to place the cleaning strip in proper alignment within the connector in order to clean the optical surfaces that are not available for cleaning at the endface of the connector. Alignment features are provided in the cleaning tip to properly position the cleaning strip relative the optical surfaces. | 08-30-2012 |
20120263423 | SPLICING CONNECTORS ALONG WITH ADAPTERS THEREFOR - Adapters for receiving high-fiber count splicing connector assemblies are disclosed. The adapter includes a splice guide insert having a first plurality of bores that extend from a first end of the splice guide and a second plurality of bores that extend from a second end of the splice guide. The splice guide aligns the optical fibers of respective splicing connector assemblies received on opposite ends of the adapter for making an optical connection. Additionally, methods are disclosed for laser processing multiple rows of fibers. | 10-18-2012 |
20130136400 | OPTICAL COUPLINGS HAVING A CODED MAGNETIC ARRAY, AND CONNECTOR ASSEMBLIES AND ELECTRONIC DEVICES HAVING THE SAME - Optical couplings for optically coupling one or more devices are disclosed. According to one embodiment, an optical coupling includes an optical coupling body, an optical interface, and a coded magnetic array located at the optical coupling body. The coded magnetic array has a plurality of magnetic regions configured for mating the optical interface. The optical coupling further includes a reflective surface within the optical coupling body and positioned along an optical path of the optical coupling body. The reflective surface is operable to redirect an optical signal propagating within the optical coupling body such that it propagates through the optical interface. The optical coupling may be configured as a plug, such as a plug of a connector assembly, or as a receptacle, such as a receptacle on an electronic device. Connector assemblies of optical cables, optical coupling receptacles, and translating shutter assemblies are also disclosed, | 05-30-2013 |
20130156377 | METHODS OF REDUCING AND/OR AVOIDING FIBER ORDERING IN A CONNECTORIZED MULTI-FIBER, FIBER OPTIC CABLE SYSTEM, AND RELATED FIBER OPTIC CABLES AND ASSEMBLIES - Methods of reducing and/or avoiding fiber ordering during preparations of a multi-fiber, fiber optic cable to provide a connectorized multi-fiber, fiber optic cable system, and related fiber optic cables and assemblies are also disclosed. The embodiments disclosed herein allow for a section of a multi-fiber, fiber optic cable to be prepared to form two or more connectorized fiber optic cables as part of a multi-fiber cable system without requiring specific fiber ordering in the fiber optic connectors. The natural ordering of the optical fibers in the fiber optic cable is fixed in place in at least one section of the fiber optic cable before the optical fibers are cut to form adjacent fiber optic connectors in the cable system. Thus, the fiber ordering between adjacent fiber optic connectors in the cable system will be the same even though the fiber ordering of the optical fibers was random during cable preparations. | 06-20-2013 |
20130322824 | OPTICAL CONNECTORS AND OPTICAL COUPLING SYSTEMS HAVING A TRANSLATING ELEMENT - Optical connectors, optical coupling systems, and methods of optical coupling are disclosed. In one embodiment, an optical connector includes a plug housing, at least one optical fiber, an internal coupling surface, and a translating element. The translating element has a first coupling surface, a second coupling surface, and at least one optical component within the translating element. The translating element is biased such that when the optical connector is in a disengaged state, the translating element is positioned toward an optical connector opening and the second coupling surface of the translating element is displaced from the internal coupling surface. When the optical connector is in an engaged state, the translating element is positioned such that the second coupling surface of the translating element is positioned at the internal coupling surface and the optical fiber is optically coupled to the optical component. | 12-05-2013 |
20130322835 | ANGULAR ALIGNMENT OF OPTICAL FIBERS FOR FIBER OPTIC RIBBON CABLES, AND RELATED METHODS - Angular alignment of optical fibers for fiber optic ribbon cables and related methods are disclosed. Employing optical fibers disposed in a ribbon matrix can increase bandwidth between two interconnection points. In one embodiment, optical fibers are angularly aligned during the process of forming a fiber optic ribbon cable. To angularly align the optical fibers, each of the optical fibers include an angular alignment feature to facilitate uniform or substantially uniform angular orientation along a cable when the optical fibers are prepared to be disposed in the ribbon matrix to form a fiber optic ribbon cable. By purposefully aligning the optical fibers during formation of the fiber optic ribbon cable, end portions of the optical fibers are aligned in the ribbon matrix. Thus, end portions of the ribbon matrix are not required to be removed to expose and align the end portions of optical fibers when the ribbon cable is connectorized. | 12-05-2013 |
20140003767 | OPTICAL FIBER SEGMENT HOLDERS INCLUDING SHIELDED OPTICAL FIBER SEGMENTS, CONNECTORS, AND METHODS | 01-02-2014 |
20140029899 | FIBER OPTIC CONNECTORS EMPLOYING MOVEABLE OPTICAL INTERFACES WITH FIBER PROTECTION FEATURES AND RELATED COMPONENTS AND METHODS - Embodiments disclosed herein include fiber optic connectors employing a movable optical interface connected by optical fibers to a fiber optic cable, components and methods. In one embodiment, the movable optical interface moves between an extended position for cleaning by the user of the movable optical interface and a retracted position to optically connect the fiber optic connector to an optical device in a mechanically-secure manner. Because the fiber optic cable employs the movable optical interfaces, embodiments described herein involve one or more fiber protection features to prevent optical fiber attenuation and/or damage to the end portions of the optical fibers. | 01-30-2014 |
20140041790 | BINDING MATERIAL PROCESSING OF GRADIENT INDEX (GRIN) RODS INTO GRIN LENSES ATTACHABLE TO OPTICAL DEVICES, COMPONENTS, AND METHODS - Embodiments for binding material processing of gradient index (GRIN) rods into GRIN lenses attachable to optical devices, components, and methods are disclosed. A cylindrical GRIN rod comprises an optical axis and a longitudinal axis at a center axis, where an index of refraction may be greatest at the optical axis. The GRIN rod includes GRIN lenses along the longitudinal axis. The GRIN lenses include a first optical surface and a second optical surface opposite the first optical surface. Separation processes and devices may separate the GRIN lenses from the GRIN rods and these processes may be automated. Other processes may polish the first and the second optical surfaces. A gripper may insert the GRIN lens into an optical device. | 02-13-2014 |
20140042647 | PROCESSING OF GRADIENT INDEX (GRIN) RODS INTO GRIN LENSES ATTACHABLE TO OPTICAL DEVICES, COMPONENTS, AND METHODS - Embodiments for processing of gradient index (GRIN) rods into GRIN lenses attachable to optical devices, components, and methods are disclosed. A cylindrical GRIN rod comprises an optical axis and a longitudinal axis at a center axis, where the index of refraction may be greatest at the optical axis. The GRIN rod includes GRIN lenses along the longitudinal axis. The GRIN lenses include a first optical surface and a second optical surface opposite the first optical surface. Separation processes and devices may separate the GRIN lenses from the GRIN rods and these processes may be automated. Other processes may polish the first and the second optical surfaces. A gripper may insert the GRIN lens into an optical device. | 02-13-2014 |
20140064667 | CABLE ASSEMBLIES, OPTICAL CONNECTOR ASSEMBLIES, AND OPTICAL CONNECTOR SUBASSEMBLIES EMPLOYING A UNITARY ALIGNMENT PIN AND TRANSLATING ELEMENT - Cable assemblies, optical connector assemblies, and optical connector subassemblies employing a translating element and a unitary alignment pin are disclosed. In one embodiment, an optical connector assembly includes a connector housing defining a connector enclosure and a connector housing opening, a unitary alignment pin including a first pin portion and a second pin portion, and a translating element including a first bore, a second bore, and an optical interface. The unitary alignment pin is secured within the connector enclosure. The first pin portion is disposed within the first bore and the second pin portion is disposed within the second bore such that the translating element translates along the first pin portion and the second pin portion within the connector enclosure. | 03-06-2014 |