Abstract: Methods of reducing and/or avoiding fiber ordering during preparations of a multi-fiber, fiber optic cable to provide a connectorized multi-fiber, fiber optic cable system, and related fiber optic cables and assemblies are also disclosed. The embodiments disclosed herein allow for a section of a multi-fiber, fiber optic cable to be prepared to form two or more connectorized fiber optic cables as part of a multi-fiber cable system without requiring specific fiber ordering in the fiber optic connectors. The natural ordering of the optical fibers in the fiber optic cable is fixed in place in at least one section of the fiber optic cable before the optical fibers are cut to form adjacent fiber optic connectors in the cable system. Thus, the fiber ordering between adjacent fiber optic connectors in the cable system will be the same even though the fiber ordering of the optical fibers was random during cable preparations.

Abstract: Optical couplings for making and optical connection between one or more devices are disclosed. In one embodiment, an optical coupling includes a coupling face, an optical interface within the coupling face, an optical component positioned within the optical interface, and at least one coded magnetic array. The at least one coded magnetic array may include a plurality of magnetic regions configured aid in mating the optical component with a corresponding optical component of a complementary mated optical coupling to a predetermined tolerance for optical communication. Optical cable assemblies and electronics devices having optical couplings with optical interfaces using coded magnetic arrays are also disclosed.

Abstract: Methods of reducing and/or avoiding fiber ordering during preparations of a multi-fiber, fiber optic cable to provide a connectorized multi-fiber, fiber optic cable system, and related fiber optic cables and assemblies are also disclosed. The embodiments disclosed herein allow for a section of a multi-fiber, fiber optic cable to be prepared to form two or more connectorized fiber optic cables as part of a multi-fiber cable system without requiring specific fiber ordering in the fiber optic connectors. The natural ordering of the optical fibers in the fiber optic cable is fixed in place in at least one section of the fiber optic cable before the optical fibers are cut to form adjacent fiber optic connectors in the cable system. Thus, the fiber ordering between adjacent fiber optic connectors in the cable system will be the same even though the fiber ordering of the optical fibers was random during cable preparations.

Abstract: Integrated silicon photonic active optical cable assemblies (ACOAs), as well as sub-assemblies and components for AOCAs, are disclosed. One component is a multifiber ferrule configured to support multiple optical fibers in a planar array. The multifiber ferrule is combined with a flat top to form a ferrule sub-assembly. Embodiments of a unitary fiber guide member that combines the features of the multifiber ferrule and the flat top is also disclosed. The ferrule sub-assembly or the fiber guide member is combined with a photonic light circuit (PLC) silicon substrate with transmitter and receiver units to form a PLC assembly. The PLC assembly is combined with a printed circuit board and an electrical connector to form an ACOA. An extendable cable assembly that utilizes at least one ACOA is also described.

Abstract: Coated optical fibers and related apparatuses, links, and methods for optically attenuating light directed to or from optical fibers are disclosed. In one embodiment, an optical fiber includes an optical fiber end. The optical fiber end may be a source end and/or a detector end, and may be angle-cleaved. A coating material is disposed on at least a portion of the optical fiber end and configured to optically attenuate a portion of light directed to the optical fiber end. The material type of the coating material and/or the thickness of the coating material may be selectively controlled to control the amount of optical attenuation. The thickness of the coating material may also be controlled to provide the desired thickness of coating material onto at least a portion of the optical fiber end. The coating material may also be selectively patterned to improve the bandwidth of a multi-mode optical link.

Abstract: Optical couplings for making and optical connection between one or more devices are disclosed. In one embodiment, an optical coupling includes a coupling face, an optical interface within the coupling face, an optical component positioned within the optical interface, and at least one coded magnetic array. The at least one coded magnetic array may include a plurality of magnetic regions configured aid in mating the optical component with a corresponding optical component of a complementary mated optical coupling to a predetermined tolerance for optical communication. Optical cable assemblies and electronics devices having optical couplings with optical interfaces using coded magnetic arrays are also disclosed.

Abstract: Coated optical fibers and related apparatuses, links, and methods for optically attenuating light directed to or from optical fibers are disclosed. In one embodiment, an optical fiber includes an optical fiber end. The optical fiber end may be a source end and/or a detector end, and may be angle-cleaved. A coating material is disposed on at least a portion of the optical fiber end and configured to optically attenuate a portion of light directed to the optical fiber end. The material type of the coating material and/or the thickness of the coating material may be selectively controlled to control the amount of optical attenuation. The thickness of the coating material may also be controlled to provide the desired thickness of coating material onto at least a portion of the optical fiber end. The coating material may also be selectively patterned to improve the bandwidth of a multi-mode optical link.

Abstract: An optical amplifier assembly comprises a Customer Interface module and a plurality of other amplifier modules. The Customer Interface module includes: (i) a customer interface configured to interact with other devices and (ii) optical and electrical connectors, connecting at least one of the other optical amplifier modules to the customer interface.

Abstract: According to one embodiment of the present invention an amplification module comprises a housing containing a plurality of optical ports. This housing: (i) at least partially encloses at least one amplification medium, (ii) provides at least one position for at least one optical filter, and (iii) includes a first optical port configured to provide both signal and pump light to the amplification module. According to an embodiment of the present invention the amplification module does not include a WDM for multiplexing pump light and signal light.

Abstract: A telemetry add/drop module includes an optical circuit. This optical circuit includes (i) at least two optical ports, (ii) at least one bidirectional light combiner/separator; and (iii) a position for another bidirectional light combiner/separator. Alternatively, the optical circuit includes (i) at least two optical ports, and (ii) at least two bidirectional light combiner/separators. According to one embodiment of the present invention at least one of these bidirectional light combiner/separators is a wavelength division multiplexer.

Abstract: According to the present invention an optical amplifier assembly comprises a plurality of optical amplifier modules. Each of these modules is being suitable for a specific intended use and provides at least one specific function, wherein at least one of the modules is marked according to its intended use.

Abstract: An Optical Power Supply module is configured to be engageable in optical communication to an optical device. This Optical Power Supply module comprises: an optical circuit including (i) at least one input port configured to receive an optical signal; (ii) an optical circuit connected to the input port and including (a) at least a one light source providing optical pump power at a first wavelength, the wavelength known to cause amplification in rare earth doped optical fiber; (b) at least one bi-directional light combiner/separator combining the optical pump power and the optical signal; and (c) at least one position for a directional optical attenuator; (iii) at least one output port connected to the optical circuit and configured to transmit the optical signal and the optical pump power at the first wavelength to the optical device.

Abstract: According to the present invention modular optical amplifier assembly, comprises at least one first module and at least one second module. The first and second modules are optically connected to one another. The first module is an Optical Power Supply module. The first module comprises an optical circuit including: (i) at least two optical ports, (ii) at least a one light source having a first wavelength known to cause amplification in rare earth doped optical fiber located between the optical ports; (iii) at least one bidirectional light combiner/separator optically coupled to the light source, and (iv) at least one position for a directional optical attenuator, located between the two optical ports. The second module is an amplification module. The second module comprises an optical circuit including (i) at least two optical ports, and (ii) at least one amplification medium.

Abstract: An optical amplifier assembly comprises a Customer Interface module and a plurality of other amplifier modules. The Customer Interface module includes: (i) a customer interface configured to interact with other devices and (ii) optical and electrical connectors, connecting at least one of the other optical amplifier modules to the customer interface.

Abstract: A method of assembling an optical amplifier comprises the steps of: (i) selecting a plurality of modules required in the optical amplifier; the plurality of modules being selected from at least types: Optical power supply module, Amplification module and at least one additional module; and (ii) assembling the modules into the optical amplifier.

Abstract: According to one embodiment of the present invention an amplification module comprises a housing containing a plurality of optical ports. This housing: (i) at least partially encloses at least one amplification medium, (ii) provides at least one position for at least one optical filter, and (iii) includes a first optical port configured to provide both signal and pump light to the amplification module. According to an embodiment of the present invention the amplification module does not include a WDM for multiplexing pump light and signal light.

Abstract: According to the present invention an optical processing module includes an optical circuit. This optical circuit includes: (i) at least two optical ports, (ii) at least one light filter situated between said two ports, and (iii) at least one position for at least one additional optical component, which when placed in said position, would be connected to said at least one light filter.

Abstract: According to the present invention, an optical monitoring and access module comprises an optical circuit including: (i) at least two optical ports, (ii) a first optical tap, (iii) at least one optical sensor optically coupled to said first optical tap; and (iv) at least one position for at least one additional optical component, which when placed in said position, would be connected to said first optical tap.

Abstract: A method of assembling an optical system includes the steps of: (i) selecting, from a plurality of optical fibers characterized by a common nominal cut-off wavelength &lgr;cn and an actual cut-off wavelength &lgr;c such that the cut-off wavelength &lgr;c of each one of this plurality of fibers is the same as the nominal cut-off wavelength &lgr;cn or differs slightly from the nominal cut-off wavelength due to manufacturing tolerances, only fibers with &lgr;c>&lgr;min, where &lgr;min is a predetermined minimum acceptable cut-off wavelength of the selected fibers; and (ii) bending at least one section of at least one of these selected fibers such that this bent section has a bend radius R, where 12 mm<R<18 mm.

Abstract: Apparatus for packaging a fiber optic device along with electronic and opto-electronic components upon a printed circuit board. Bend members having arcuate shaped guide surfaces for directing fibers between various components are strategically mounted upon the top surface of the board. Passive fiber optic components are also mounted upon support means between bend members so that the fibers entering and exiting the passive component run tangent to the bend radius of the bend members. The radius of curvature of the bend members is within the bend tolerance of the fibers used in the device. The bend members and support members are formed of a material having a thermal coefficient of expansion that is about equal to that of the board material whereby thermally induced stresses on the board mounted components are minimized.