Abstract: An adapter for an optical fiber connector has a switch mounted therein and an actuation lever contained therein for actuating the switch to turn optical power on. The lever has an enlarged rear portion separated from a front portion by a flexible web. The adapter has an opening therein for receiving a connector plug which is masked by the enlarged portion of the lever when in the operative position. When a plug is to be inserted, the enlarged portion is bent up to unmask the opening. After the plug is inserted, the rear portion is aligned with the front portion of the lever and the lever slid forward to actuate the switch. In the forward position, the enlarged portion prevents access to the latching arm of the connector plug so that it cannot be removed while the power is on. The lever must be slid to the rear, turning off the power, before the connector can be removed.

Abstract: An adapter for an optical fiber connector has a switch mounted therein and an actuation lever contained therein for actuating the switch to turn optical power on. The lever has an enlarged rear portion separated from a front portion by a flexible web. The adapter has an opening therein for receiving a connector plug which is masked by the enlarged portion of the lever when in the operative position. When a plug is to be inserted, the enlarged portion is bent up to unmask the opening. After the plug is inserted, the rear portion is aligned with the front portion of the lever and the lever slid forward to actuate the switch. In the forward position, the enlarged portion prevents access to the latching arm of the connector plug so that it cannot be removed while the power is on. The lever must be slid to the rear, turning off the power, before the connector can be removed.

Abstract: A high density optical connecting block 100 is mounted in a relatively thin, flat panel 10, and is constructed as an array of identical cells 110 that are linked together as a one-piece unit. The connecting block has a front-to-back depth that is greater than ten millimeters for imparting flexural rigidity to the panel. The array includes at least twelve cells that are arranged in two or more rows and two or more columns. Each cell has a front side that is shaped to receive and interlock with a duplex optical connector 50, and a back side that is shaped to receive and interlock with two simplex optical plugs 20. The duplex connector is a unifying structure that yokes a pair of simplex optical plugs 20-1, 20-2 into a duplex configuration.

Abstract: A high density optical connecting block 100 is mounted in a relatively thin, flat panel 10, and is constructed as an array of identical cells 110 that are linked together as a one-piece unit. The connecting block has a front-to-back depth that is greater than ten millimeters for imparting flexural rigidity to the panel. The array includes at least twelve cells that are arranged in two or more rows and two or more columns. Each cell has a front side that is shaped to receive and interlock with a duplex optical connector 50, and a back side that is shaped to receive and interlock with two simplex optical plugs 20. The duplex connector is a unifying structure that yokes a pair of simplex optical plugs 20-1, 20-2 into a duplex configuration.

Abstract: A high density optical connecting block 100 is mounted in a relatively thin, flat panel 10, and is constructed as an array of identical cells 110 that are linked together as a one-piece unit. The cells have a front-to-back depth that is greater than ten millimeters for imparting flexural rigidity to the panel. The array includes at least twelve cells that are arranged in two or more rows and two or more columns. Each cell has a front side that is shaped to receive and interlock with a duplex optical connector 50, and a back side that is shaped to receive and interlock with two simplex optical plugs 20. The duplex connector is a unifying structure that yokes a pair of simplex optical plugs 20-1, 20-2 into a duplex configuration.

Abstract: A high density optical connecting block 100 is mounted in a relatively thin, flat panel 10, and is constructed as an array of identical cells 110 that are linked together as a one-piece unit. The cells have a front-to-back depth that is greater than ten millimeters for imparting flexural rigidity to the panel. The array includes at least twelve cells that are arranged in two or more rows and two or more columns. Each cell has a front side that is shaped to receive and interlock with a duplex optical connector 50, and a back side that is shaped to receive and interlock with two simplex optical plugs 20. The duplex connector is a unifying structure that yokes a pair of simplex optical plugs 20-1, 20-2 into a duplex configuration.

Abstract: An optical connector is disclosed for terminating an optical cable 10 comprising a plastic optical fiber 11 surrounded by a protective jacket 12. The connector includes a housing having an exterior latch 201 that secures it to an adapter 31. The latch is constructed as a cantilever with its fixed end positioned toward a front end of the housing. The connector further includes a cable-holding structure that attaches to the jacket of the optical cable in such a manner that the plastic optical fiber 11 connects to an associated optical device without the use of a ferrule. One cable-holding structure includes a guide tube 45 that is made from metal and is pressed, or insert molded, into the back end of one plastic housing 40. A portion of the guide tube protrudes from the back end of the housing and is crimped onto the optical cable. Here, the optical cable is immovably attached to the housing.

Abstract: The specification describes techniques for chemically machining extruded glass preforms used to draw glass ferrules for optical fiber connectors. Using the chemical machining technique the dimensions of the preform, including OD, ID, and the OD to ID ratio can be adjusted so that the dimensions of drawn ferrules meet strict dimensional standards. The technique is especially useful for adjusting the dimensions of extruded preforms that have an inherent bow along in the length of the preform. The technique allows adjustment in dimensions while preserving a desired OD to ID ratio. Also described are techniques for reducing eccentricity and/or ellipticity of hollow bore glass preforms.

Abstract: A method and apparatus for manufacturing an optical connector subassembly provide an improved device at lower cost. The optical connector includes a plastic base member 150 which is overmolded onto a cylindrical ferrule 140 having an axial passageway 145 which extends from one end face 141 of the ferrule to the other 142. A mold 900 includes two parts 910, 960 which are joined together before heated and pressurized thermoplastic material is injected. The ferrule is held within a first channel 914 of the mold and a spring-loaded core pin 950 is held within a second channel 964 of the mold. These channels are coaxially aligned when the mold parts are joined together. The core pin includes a conical point 951 at one end which enters the axial passageway of the ferrule before the thermoplastic material is injected. A third channel 912, 962 receives the thermoplastic material and routes it into the first and second channels.

Abstract: A one-piece (unipartite) jack receptacle 40 is molded from thermoplastic material into a generally rectangular shape to provide a compact structure for high-density optical terminations. The receptacle includes a pair of cavities 460, each having an opening in its front end, and each having an opening 422 in its back end for receiving a cylindrical alignment sleeve 440. A U-shaped opening extends from a top-side surface 415 of the receptacle into each cavity to form a cantilever 410, which may be used to hold the receptacle within a panel 200. Molded into the sidewalls of each cavity are retaining surfaces 432 for holding an optical connector within the cavity. The retaining surfaces are located directly beneath the U-shaped opening 463 to facilitate molding. Heretofore, comparable jack receptacles have been assembled from multiple parts; and this has become more costly and complex as the size of jack receptacles has decreased.