An optical fiber fusion splicer includes an image acquisition unit, a condition setting unit, and a fusion splicing unit. The image acquisition unit acquires an image including each of end surfaces of first and second optical fibers that are splicing targets in a state where the end surfaces of the first and second optical fibers are disposed to face each other. The condition setting unit sets splicing conditions in accordance with a state of each of the end surfaces by identifying the state of each of the end surfaces on the basis of the image. The fusion splicing unit fusion-splices the first and second optical fibers together by means of discharge between a pair of electrode bars in accordance with the splicing conditions set by the condition setting unit.

Arrays of fiber pigtails can be used to project and receive light. Unfortunately, most fiber pigtail arrays are not aligned well enough for coherently combining different optical beams. This imprecision stems in part from misalignment between the optical fiber and the endcap spliced to the end of the optical fiber. The endcap is often polished, curved, or patterned, causing the light emitted by the endcapped fiber to refract or diffract as it exits the endcap. This refraction or diffraction shifts the apparent position of the beam waist from its actual position. Measuring this virtual beam waist position before and after splicing the endcap to the fiber increases the absolute precision with which the fiber is aligned to the endcap. This increase in absolute precision reduces the deviation in virtual beam waist position among endcapped fibers, making it easier to produce arrays of endcapped fibers aligned precisely enough for coherent beam combining.

Various embodiments and method relating to an optical fiber curvature measurement system are described herein. The optical fiber curvature measurement system includes a controller and a rotation stage. The rotation stage includes a central axis, a first end, and a second end. The central axis extends from the first end to the second end of the rotation stage. The rotation stage includes an optical fiber channel extending from the first end of the rotation stage to the second end of the rotation stage. The rotation stage is operationally coupled with the controller and configured to rotate about the central axis of the rotation stage. An optical fiber may be positioned within the optical fiber channel. The optical fiber curvature measurement system also includes a light source positioned to emit light onto the optical fiber channel at an oblique angle from the central axis of the rotation stage.

An optical connector for terminating a cable containing one or more multicore fibers. The connector has a plug housing, a ferrule disposed inside the housing, a rotatable frame, and a multicore fiber (MCF) stub having a length of a first MCF a portion of which is fixed inside the ferrule so that a first endface of the fiber is exposed at the front end of the ferrule. An opposite endface of the first MCF is cleaved for fusion splicing to a second MCF in the cable to be terminated. The ferrule also has a flange, and the frame is formed to engage the flange for rotation so that cores in the first MCF can be aligned and positioned in a prescribed orientation relative to the plug housing, and cores in the second MCF can be aligned with corresponding cores in the first MCF when the first and the second MCFs are fusion spliced to one another.

Techniques for aligning each of a plurality of optical fibers for coupling to a photonic integrated circuit (PIC). Transmission is detected from each respective optical fiber to the PIC using a probe, and the respective optical fiber is aligned based on the detected transmission. Each of the plurality of optical fibers is coupled to the PIC using at least one of: (i) laser splicing, (ii) laser spot welding, or (iii) arc welding,

The invention relates to a method and to an assembly (200) for localizing an optical coupling point (11) and to a method for producing a microstructure (100) at the optical coupling point (11). The method for localizing an optical coupling point (11) comprises the following steps: a) providing an optical component (10), which comprises an optical coupling point (11), the optical coupling point having an interaction region (15) lying outside of a volume encompassed by the optical component (10); b) producing optical radiation in a production region (120), the production region (120) overlapping at least partly with the interaction region (15) of the optical coupling point (11), light being applied to a medium (19) located in the production region (120), which light is modified by the medium (19) in such a way that the optical radiation is thereby produced; c) sensing at least part of the produced optical radiation in a sensing region (130), the sensing region (130) overlapping at least partly with the interaction region (15) of the optical coupling point (11), and determining a spatially resolved distribution of the sensed part of the produced optical radiation; and d) determining the localization of the optical coupling point (11) from the determined spatially resolved distribution of the sensed part of the produced optical radiation, the optical radiation being produced or at least the part of the produced optical radiation being sensed through the optical coupling point (11). The optical coupling point (11) can thereby be precisely localized with a relative positioning tolerance of better than 1 μm. Thus, low coupling losses of an optical connection to the optical component (10) can be achieved and microstructures (100) can be precisely placed at the optical coupling point (11).

Optical fiber mass splice methods and assemblies are provided. A method may include securing a fiber clamp to a fiber setting fixture, the fiber setting fixture including a fiber alignment block and a backstop. A plurality of fiber grooves may be defined in the fiber alignment block. The method may further include inserting a plurality of optical fibers into the fiber setting fixture such that each of the plurality of optical fibers is disposed in one of the plurality of fiber grooves and contacts the backstop. The method may further include loading, after the inserting step, each of the plurality of optical fibers into the fiber clamp. The method may further include clamping the plurality of optical fibers in the fiber clamp.

Disclosed is a method and system applicable to attaching a single or multiple optical fibers in sequence to a photonic integrated circuit enabling precise control of optical fibers and/or multiple types of optical fibers and/or at any pitch. The system and method provide optical alignment and in situ attachment of one or more optical fibers to a photonic integrated circuit chip using a photo-curable adhesive, wherein curing light is delivered to the adhesive by the optical fiber being attached.

An optical fiber arrangement method includes: preparing an intermittently connected optical fiber ribbon including optical fibers arranged side by side at a first pitch larger than a fiber diameter; holding a non-connecting region of the optical fiber ribbon with a holder, where connecting portions intermittently connect the optical fibers extending out from the holder to each other; changing a width of the optical fiber ribbon in an interior of the holder; and arranging the optical fibers, extending out from the holder, with intervals of the optical fibers changed from the first pitch to a second pitch smaller than the first pitch by removing the connecting portions in a state where the holder is holding the optical fibers.

Aspects and techniques of the present disclosure relate to an apparatus for providing 200 micron, or smaller, coated optical fibers with a 250 micrometer pitch diameter in preparation for insertion into a Multi-fiber Push On connector (MPO) and/or splicing apparatus. The apparatus can sort, arrange, and clamp optical fibers into a proper sequence to allow the coated optical fibers to be aligned for processing, for example, connectorization and/or splicing. The apparatus includes a separator element that defines grooves for receiving and sequencing coated optical fibers with respect to each other to set a uniform pitch diameter.