There is provided an adapter tip to be employed with an optical-fiber connector endface inspection microscope and an optical-fiber connector endface inspection microscope system suitable for imaging the optical-fiber endface of an angled-polished optical-fiber connector deeply recessed within a connector adapter. The adapter tip or microscope system comprises a relay optical system comprising a Rhomboid prism. The Rhomboid prism being disposed so as to receive light reflected from said optical-fiber endface during inspection and laterally shift the light beam reflected from the angled-polished optical-fiber endface.

At least some embodiments of disclosure provide a method and device for optical fiber monitoring and an optical fiber adapter. The method includes: a device for monitoring the optical fiber for performing optical fiber monitoring is installed in an optical fiber adapter and the optical fiber monitoring is performed by using the optical fiber adapter with the device for monitoring the optical fiber. The problem that the device for monitoring the optical fiber has complex wiring and a deployment position is limited is solved. And effects that the wiring complexity of the device for monitoring the optical fiber is reduced, and the deployment position is flexible and convenient are achieved.

An optical fiber inspection system may include an alignment guide having a sleeve portion and a mechanical key structure. The sleeve portion may comprise a first opening arranged to be proximal to one or more optical components in an inspection device and a second opening arranged to be distal to the one or more optical components when the alignment guide is removably engaged with the inspection device. The mechanical key structure may be located adjacent to the second opening and have a shape to engage a geometry of one or more recesses in a bulkhead. Accordingly, the alignment guide may stabilize the inspection device at a particular angle relative to an end face of an object in a field of view of the one or more optical components when a shaft of the inspection device is inserted into the bulkhead.

An example system for inspecting fiber optic cables includes: a fixture including a body configured to hold a plurality of fiber optic cables, the fixture including a front portion defining a plurality of apertures positioned adjacent to ends of the fiber optic cables; and an adapter including two or more pin members extending therefrom, the two or more pin members being configured to be positioned in two or more of the plurality of apertures in the fixture to hold the fixture relative to the adapter.

A method for providing spectral beam combining (SBC) including generating a plurality seed beams each having a central wavelength and a low fill factor profile, where the wavelength of all of the seed beams is different; amplifying the seed beams; causing the amplified beams to expand as they propagate so as to be converted from the low fill factor profile to a high fill factor profile where the high fill factor profile tapers to a lower value at a perimeter of each beam; causing a wavefront of the converted beams to flatten to provide a plurality of adjacent SBC beams having different wavelengths with minimal overlap and a minimal gap between the beams; collimating the SBC beams; and directing the collimated SBC beams onto an SBC element that spatially diffracts the individual beam wavelengths and directing the beams in the same direction as a combined output beam.

An optical scanning adapter for shifting the imaging axis of an inspection probe for inspecting fiber endfaces of a multiple-fiber connector includes a housing, a fitting tip having a mating interface for interfacing with the connector, an imaging assembly, an x-direction driving mechanism, a y-direction driving mechanism, and a connecting portion for connecting an inspection probe. The imaging assembly includes a first lens, a first reflective surface, a second reflective surface, and a second lens. The connector endfaces are placed on the front focal plane of the first lens. The x-direction driving mechanism shifts the imaging axis of the imaging assembly along a first direction by translating the first lens and the first reflective surface together, whereas the y-direction driving mechanism shifts the imaging axis along a second direction orthogonal to the first direction by turning the second reflective surface about the optical axis of the second lens.

A method and system for reading a marker embedded in a fiber optic connector, and a connector configured to be read by the method and system. The connector includes an outer assembly and a marker that is overlaid by the outer assembly. To read the marker, the connector is illuminated with an illuminating light in a first spectral band, and an image is formed using the light within the first spectral band that is reflected from the fiber optic connector. The reflected light includes at least a portion of the illuminating light which was transmitted through the outer assembly and reflected back toward a reader by the marker. Data contained in the marker is then extracted from the image.

Aspects of the disclosure are drawn to methods for producing a fused connector termination. An exemplary method may include setting a specification requirement to be met by the fused connector termination and applying an amount of heat to a proximal region of an unfused connector termination. The proximal region of the unfused connector termination may include an inner optical fiber coaxially positioned within an outer ferrule, and applying the amount of heat may at least partially fuse the optical fiber to the outer ferrule to form an at least partially fused connector termination. The method may also include imaging the proximal region of the at least partially fused connector termination and determining, based on the imaging, whether the proximal region of the at least partially fused connector termination meets the specification.

In some implementations, an optical component of a microscope may capture an image of a profile of a ferrule and a connector of an optical fiber based on the ferrule being received by a first opening of a first connector adapter of the microscope. A mechanical axis of the ferrule may be orthogonal to an optical path from a camera of the microscope to the ferrule when the ferrule is received by the first opening. One or more processors associated with the microscope may process the image to determine a measurement of a chamfer of the ferrule. The optical component may capture an image of an endface of the ferrule based on the ferrule being received by a second opening of a second connector adapter. The mechanical axis of the ferrule may be axially aligned with the optical path when the ferrule is received by the second opening.

A fiber optic connection inspection apparatus and method includes an adapter housing fitted to a video microscope camera configured to observe and records images of a Direct Contact and Expanded Beam fiber optic connector assemblies. The adapter housing is configured to rotatably connect the camera for 360 degree rotation about a longitudinal axis of the adapter housing, assuring inspection of a larger field of view. The field of view represents the three-dimensional nature of the various sectors of a fiber optic connector. The rotation of the camera permits the instrument to visualize the complete connector, enabling the technician to make an informed decision which surfaces to clean to improve signal transmission. The adapter housing may be constructed of soft material that enables camera manipulation to provide a comprehensive view of the optical connector surfaces. The rotating adapter housing may be 3D printed which enables flexibility of design and production.