Abstract: Apparatuses and methods for adjusting the spectral response of an optical waveguide grating include a longitudinal optical waveguide grating attached to a support member having a centroidal axis. The support member is configured for longitudinal bending and rotating about its centroidal axis. The spectral response of the optical waveguide grating is adjusted by bending and rotating the support member about its centroidal axis.

Abstract: An apparatus that exposes only a selected portion of a length of optical fiber to a hydrogen atmosphere loading process. The apparatus includes a loading chamber that encloses at least the selected portion of the optical fiber and contains a hydrogen hydrogen atmosphere. At least one heating element regionally heats the hydrogen atmosphere surrounding the selected portion. The heating element may heat the hydrogen atmosphere to a temperature of at least 250° C.

Abstract: An apparatus and method for adjusting the spectral response of a selected channel within an optical waveguide grating includes a grating attached to a support member. An adjusting mechanism applies two bending moments to the grating support member on both sides of the selected channel. The spectral response of the selected channel is adjusted by altering the bending moments.

Abstract: A method for increasing the photosensitivity of a selected portion of an optical fiber and for producing a grating in the selected portion of an optical fiber. The method includes the step of placing the selected portion of the optical fiber in a hydrogen containing atmosphere. The volume of the hydrogen-containing atmosphere immediately surrounding only the selected portion of the optical fiber is heated to a temperature of at least 250° C. Only the selected portion of the optical fiber is exposed to the heated volume of the hydrogen-containing atmosphere at a temperature of at least 250° C. for a predetermined time.

Abstract: An apparatus that exposes only a selected portion of a length of optical fiber to a hydrogen atmosphere loading process. The apparatus includes a loading chamber that encloses at least the selected portion of the optical fiber and contains a hydrogen hydrogen atmosphere. At least one heating element regionally heats the hydrogen atmosphere surrounding the selected portion. The heating element may heat the hydrogen atmosphere to a temperature of at least 250° C.

Abstract: A method for increasing the photosensitivity of a selected portion of an optical fiber and for producing a grating in the selected portion of an optical fiber. The method includes the step of placing the selected portion of the optical fiber in a hydrogen containing atmosphere. The volume of the hydrogen-containing atmosphere immediately surrounding only the selected portion of the optical fiber is heated to a temperature of at least 250° C. Only the selected portion of the optical fiber is exposed to the heated volume of the hydrogen-containing atmosphere at a temperature of at least 250° C. for a predetermined time.

Abstract: A package is provided for an optical fiber that includes a Bragg grating. The package includes a retaining member that supports the optical fiber and contacts the optical fiber along at least substantially the entire length of the Bragg grating. A housing is provided which is adapted to receive the retaining member therein. The housing has a conductivity below that of the retaining member so that the Bragg grating is maintained at a substantially uniform temperature.

Abstract: An optical module for interconnecting two or more optical fibers has a microreplicated waveguide element which is integrally formed on the same substrate with a splice element. In one embodiment, the module has three plates, a bottom plate, a cover plate, and a top plate, all contained within a common housing. The bottom plate has fiber-receiving grooves and fiber alignment grooves at its ends, the fiber alignment grooves being aligned with waveguide channels formed on the central portion of the bottom plate. The cover plate is used when forming the cores of the waveguide channels, to force residual curable, waveguide material into flow channels adjacent the waveguide channels, and this material, when cured, adheres the bottom and cover plates together. The top plate is used to clamp fibers which are held in the fiber alignment grooves, with the center of the fibers aligned with the core of the waveguide channels.

Abstract: A modular, multifiber connector comprising a plug and a receptacle whose outward appearance and installation is similar to a convention RJ45 jack for copper conductors. The plug includes a body having a surface with several fiber-receiving grooves, and the plug fibers terminate along an intermediate section of the grooves. The receptacle includes a housing having an opening, and a plate which is slidably mounted inside the housing. The plate is biased toward the opening and has several more fiber-receiving grooves. The receptacle fibers approach the plate at an oblique angle causing them to bend as they contact the grooves of the plate. When the plug is inserted into the opening, its forward end contacts the plate and pushes it back. As the plate retracts, the terminal portions of the fibers in the receptacle (which are not secured to the plate) become free to flex, and position themselves in the corresponding grooves of the plug.

Abstract: A fiber optic connector for a fiber distributed data interface (FDDI) has a keying element located along the centerline of the plug which may be rotated to provide different polarizations for the plug. The plug has a cable entering one end, and breaking out into two fibers which terminate in ferrules at the other end of the plug. The keying element has a post which is slidably received in a hole through the plug, the hole positioned in a groove located along the centerline of the plug; an annular flange is formed at the distal end of the post to retain it within the hole. The post is molded with a square keyway block which has two channels in its upper surface. The channels are orthogonal, and one is located along the centerline of the block while the other is located along one side of the block. The plug mates with a receptacle having a spline on its inner surface, located in one of four possible configurations near the centerline of the receptacle.

Abstract: An improved fiber distribution panel including fiber connecting and splicing modules which are slidable into and out of a housing which is formed to support a plurality of said modules. Each module is provided with means for supporting a fiber connector at an angle with respect to the front edge thereof allowing access to the connectors and supports a booklet for storing slack fiber and for supporting permanent fiber connectors within said module.

Abstract: A communication cable applicator and method in which a communication cable component supply including two rolls of pressure sensitive adhesive tape and a plurality of lengths of communication conductors supported and guided on a frame across a resilient applicator roller on which the conductors are sandwiched between the tapes and the composite is applied to a floor prior to carpeting as a user pushes the apparatus across the floor.