Abstract: The present invention is a passive receive module for use with an OTDR for determining polarity of a cable under test. Only one position of the module connector of the receive module includes a filling and all other positions are occupied with a reflective component with a reflective characteristic distinct from that of the filling. Only one position at the OTDR end of the cable will receive a distinct reflection from all of the other positions. Polarity may be determined from these positions.

Abstract: The test device of the present invention is configured to test the continuity and polarity of a plurality of fibers housed by a cable that extends between the multi-fiber connectors on either end of the cable. In its most basic form, the test device of the present invention includes first and second light sources; an optical splitter positioned between the second light source and the connector at the first end of the cable housing the plurality of fibers under test; and a receiver and configured for optical communication with the second end of the cable. The first light source creates a first light pattern, which is distinct from a second light pattern created by the second light source.

Abstract: A digital fiber optic connector imaging system that can automatically capture two or more images of the endface of a multifiber connector, wherein the captured images as a group have sufficient resolution and a sufficient FOV to be used to perform a manual or automatic pass-fail analysis of the endface of every fiber terminated by the connector under inspection. In one or more embodiments, the imaging system comprises an illumination source that can operate at two or more wavelengths, one wavelength at a time, and a FOV-shifting component that includes one or more, fixed dichroic mirrors and one additional dichroic or broadband mirror. In other embodiments, the imaging system comprises a single-wavelength illumination source, an image beam splitter, and two or more image sensors located on two image planes.

Abstract: The present invention is an Optical Time-Domain Reflectometer (OTDR) with an integrated Launch Cable that has a retractable lead, designed to work as a standalone instrument, or under the control of an external device such as a smartphone, tablet, PC, or server.

Abstract: The present invention is a hybrid ferrule which is able to be connected to both, angle polished and flat polished, MPO connectors; a test device including the above mentioned hybrid ferrule; and a test kit, including the above mentioned test device with hybrid ferrule. The hybrid ferrule of the present invention includes first, second, and third surfaces which are designed in a special way to ensure the high quality connection with SM or MM type connectors. A hybrid fiber connector having an integrated end, a connection end, two sides, a flat center, and an optical fiber embedded in the flat center parallel to and halfway between the two sides. The connection end includes left and right edges and first, second, and third surfaces. The first surface angles upward from said left edge of said connection end to a first point, the second surface extends flat between the first point and a second point, and a third surface angles downward between the second point and the right edge of said connection end.

Abstract: A handheld wavelength meter that includes a housing that encloses a non-stable reference signal source, an interferometer with rotating retroreflectors, optical-electrical converters, a frequency multiplier, and a controller.

Abstract: A optical time domain reflectometer (OTDR) which sends and receives pulses for multiple frequencies down a fiber under testing (FUT). These frequencies can include frequencies for testing a live FUT and frequencies for testing a dark FUT. The pulses of the various frequencies are sent and received through a single optical connection with the FUT. The number of connections necessary to test the fiber is thus reduced. The OTDR may also include a built in passive optical network (PON) power meter, which measures the power level of the fiber over the same single optical connection.