Abstract: An optical fiber splicing device includes a clip (20) which aligns and secures cylindrical rods (28, 30 and 32) utilized within a three-rod optical fiber splicing device. The clip (20) is a generally cylindrically shaped component which is made of a resilient material and is positionable so as to encase three cylindrical rods (28, 30 and 32). The clip (20) comprises a circular body portion (22) and two protruding leg portions (24 and 26) which extend from an point on the outer periphery of clip body (22). The two leg portions (24 and 26) are constructed and oriented such that they may be manipulated to controllably expand the inner diameter of clip body (22). To facilitate an optical fiber splice or connection, the clip (20) of the present invention allows the clip body (22) to be expanded to loosen the grip on rods (28, 30 and 32) held therein, thereby allowing the optical fiber ends to be inserted between the rods.

Abstract: The splice verification system of the present invention verifies the efficiency of an optical splice by measuring the scattered light escaping from the splice. Specifically, the preferred embodiment performs such scattered light measurement within a photodetection area which is substantially free of all ambient light. Furthermore, the verification system includes a reference power module which, prior to creating an optical splice, measures the level of the optical signal being transmitted out of the end of an active fiber. The present invention then provides means to correlate the level gauged as a reference signal level relative to the amount of scattered light lost from the optical splice. The ratio of these two measured light levels may then be used to determine whether the amount of scattered light lost from the optical splice is acceptable given the particular constraints of the optical system in which the splice is employed.

Abstract: An optical fiber splicing device includes a clip (20) which aligns and secures cylindrical rods (28, 30 and 32) utilized within a three-rod optical fiber splicing device. The clip (20) is a generally cylindrically shaped component which is made of a resilient material and is positionable so as to encase three cylindrical rods (28, 30 and 32). The clip (20) comprises a circular body portion (22) and two protruding leg portions (24 and 26) which extend from an point on the outer periphery of clip body (22). The two leg portions (24 and 26) are constructed and oriented such that they may be manipulated to controllably expand the inner diameter of clip body (22). To facilitate an optical fiber splice or connection, the clip (20) of the present invention allows the clip body (22) to be expanded to loosen the grip on rods (28, 30 and 32) held therein, thereby allowing the optical fiber ends to be inserted between the rods.

Abstract: In a plug-type optical fiber connector low loss can be achieved, without any active alignment of the fiber cores, if the two cylindrical plugs used in the connector are "contiguous" plugs, i.e., derived from contiguous segments of the tubular stock from which the plugs are produced, and if the plugs are arranged such that the "contiguous" ends of the plugs are the mating ends, and such that the rotational relationship between the plugs is substantially the one that existed prior to sectioning. The inventive connector comprises two contiguous plugs and includes features that permit identification of the contiguous ends and of the rotational relationship. In a preferred embodiment, the tubular stock is drawn glass stock, the two contiguous segments are left joined but scored circumferentially to permit easy separation in the field, with a longitudinal groove in the outer cylinder surface of the contiguous segments identifying the original rotational relationship.

Abstract: An optical fiber connector capable of producing very low-loss single-mode fiber connections is disclosed. The connector utilizes two capillary cylinders for holding the fiber ends, and a multiplicity, preferably three, cylindrical alignment rods that provide multi-point support for the cylinders. At least one, preferably two, of the alignment rods carry a "flat" extending from one end of the rod for a substantial fraction of the length of the rod. The assembly is held together by appropriate means, e.g., a substantially triangular alignment fixture. The presence of antiparallel flat-carrying alignment rods permits simple alignment of the two fiber cores, typically by means of rotation of one or both of the capillary cylinders.

Abstract: Optical fibers are spliced by a technique that yields very low loss and accommodates fibers having different outer diameters or having nonconcentric cores. The technique is especially useful for single mode optical fibers, and splice losses of less than 0.1 db in a wavelength range of about 1.3 to 1.55 micrometers is typically obtained. The splice comprises a slotted tube surrounding abutted fiber ends, with the tube being at least partially filled with cement. An outer cylindrical sleeve is optionally provided for increased strength. In splicing the fibers, the fibers are aligned by means of a scattered light detector comprising a slotted tube surrounding a portion of the fiber, and a detector at one end of the tube. A sensitive null indication is obtained which provides for precise alignment of the fiber cores.