A fiber optic connector for connecting one or more optical fibers to a fiber optic component includes: a ferrule configured to receive the one or more optical fibers; a ferrule holder configured to be coupled to the ferrule, wherein the ferrule and ferrule holder forms a ferrule support assembly when coupled together; and a shroud configured to be positioned about the ferrule support assembly and connectable to the fiber optic component. The ferrule support assembly and the shroud are configured so that the ferrule support assembly is movable relative to the shroud to positions outside the shroud when the shroud is disconnected from the fiber optic component, and the ferrule support assembly is confined within the shroud when the shroud is connected to the fiber optic component. A method of forming a fiber optic assembly using such a fiber optic connector is also disclosed.

An optical fiber array includes: a multicore optical fiber in which the outer peripheral shape of cladding in a cross section has first and second convex surfaces symmetric with respect to a first axis, and first and second surfaces symmetric with respect to a second axis and closer than extensions of the first and second convex surfaces to the second axis; an arrangement component including a groove having a trapezoidal shape having first and second side surfaces mutually facing such that sectional shapes become closer toward a grove bottom, and a bottom surface; and a pressing member. With the first surface in surface contact with the pressing member, the first convex surface or a boundary portion between the first convex surface and the second surface, and the second convex surface or a boundary portion between the second surface and the second convex surface are in contact with the first and second side surfaces, respectively.

A behind-the-wall optical connector having an outer housing configured to be inserted into an adapter with a corresponding inner surface, and a latch attached to one side of housing configured to lock the connector into an adapter opening. The latch is further configured with a locking channel and guide to accept a pull tab with a catch at one end, the pull tab releases the connector from the adapter opening when the tab is pulled rearward or away from the adapter. The ferrule assembly is inserted into a first end of the housing and when latched to the adapter, the assembly is retained in the housing without any locking structure therein.

An optical fiber cable is disclosed. The optical fiber cable comprises an optical cable including optical fibers and a sheath where the optical fibers are arranged in a first array, and a holder. The optical fibers have first extending parts that extend outside from the sheath, and second extending parts that extends from the first extending parts to the tips of the optical fibers. The holder comprises a first portion that houses therein transition portions where the first extending parts transitions from the first array to a second array, and a second portion that holds parts of the first extending parts in the second array. The second portion is configured to hold the first extending parts in a manner such that a mutual positional relationship among the second extending parts keeps the same state as a mutual positional relationship among the first extending parts at the second portion.

The present invention relates to a fibre optic fusion splicing technique, in particular to a fibre optic fusion splicer for reliable and stable fibre optic fusion splicing, that is characterized by comprising: an alignment part for fixing and aligning first and second optical fibres that are to be fusion spliced; a fusion splicing module having an electrode bar for fusion splicing the first and second optical fibres that are fixed to and aligned in the alignment module; an optical module for photographing the aligned state of the first and second optical fibres aligned by the alignment module, and the fusion-spliced state of the first and second optical fibres fusion-spliced by the fusion splicing module; a support part in which the fusion splicing module and the optical module are mounted; and a lift module for moving the support part up and down.

A fiber alignment device includes: a fixation block; an alignment element having a first end portion fixed in the fixation block and a second end portion formed with a protrudent platform, an alignment groove being formed in the alignment element and extending to an end of the protrudent platform in a central axis of the alignment element; an alignment sleeve having a first end portion fitted on the second end portion of the alignment element; and a spring element having a first end extending into the alignment sleeve and pressed against the alignment groove in the protrudent platform. The front end of the ferrule assembly is inserted into the alignment sleeve and when the fiber is inserted into the alignment groove of the alignment element, the position accuracy of the fiber in the fiber bore of the ferrule assembly is calibrated to reach position accuracy of the fiber in the alignment groove of the alignment element. A high precision fiber optic connector may be manufactured with a low precision ferrule. The spring element is pressed against the fiber inserted into the alignment groove, so that an eccentricity orientation of a center of the fiber with respect to a center of the alignment element is adjusted to a predetermined orientation and held in the predetermined orientation. Thereby, it may eliminate a process of identifying and adjusting the eccentricity orientation of the center of the fiber.

An optical subassembly includes a receptacle, a ferrule and a ferrule fastening component. The ferrule and the ferrule fastening component are connected with the receptacle. The ferrule fastening component includes a fastening portion and a blocking portion connected with each other. The fastening portion is fastened with the receptacle, and the blocking portion touches the ferrule.

A behind-the-wall optical connector having an outer housing configured to be inserted into an adapter with a corresponding inner surface, and a latch attached to one side of housing configured to lock the connecter into an adapter opening. The latch is further configured with a locking channel and guide to accept a pull tab with a catch at one end, the pull tab releases the connector from the adapter opening when the tab is pulled rearward or away from the adapter. The ferrule assembly is inserted into a first end of the housing and when latched to the adapter, the assembly is retained in the housing without any locking structure therein.

An optical subassembly includes a receptacle, a ferrule and a ferrule fastening component. The ferrule and the ferrule fastening component are connected with the receptacle. The ferrule fastening component includes a fastening portion and a blocking portion connected with each other. The fastening portion is fastened with the receptacle, and the blocking portion touches the ferrule.

A process and tool for reshaping and resizing grooves that were pre-formed in a pair of ferrules halves of an optical fiber ferrule. The pre-formed grooves are further subject to a separate, subsequent reshaping and resizing step using the tool and a gauge that may be a bare section of optical fiber or a pin. The ferrule halves are aligned, and using the pre-formed grooves as guides for the gauge optical fiber or gauge pin, the ferrule halves are compressed together with the gauge optical fiber or gauge pin therebetween, thereby reshaping and resizing the respective grooves on the ferrule halves. After reshaping and resizing, the resultant groove that is finally formed on each ferrule halve would be precisely shaped, sized and located with respect to the external alignment surface of each ferrule halve. The ferrule halves may be used to terminate an optical fiber cable.