Switching technology may be incorporated into various systems, components, and/or architectures in a fiber optic network to promote network reconfigurability and design flexibility. A signal access unit comprises an input, an output, an access port, a switch arrangement including a switch, and a controller. The switch optically couples the input to the output and not to the access port when in a first configuration, and optically couples the access port to at least one of the input and the output without optically coupling the input and the output together when in a second configuration. The controller is configured to receive an indication of a selected wavelength and to operate the switch arrangement to change the switch between the first and second configurations based on the indication of the selected wavelength.

An optical communications system includes a laser transmitter to generate an optical signal and a first optical fiber network coupled to transmit the optical signal from the laser transmitter system. A first latchable, asymmetric coupler is disposed along the first optical fiber network to receive the optical signal, and has a first tap output that receives a selected and alterable first fraction of the optical signal. A second latchable, asymmetric coupler is disposed along the first optical fiber network to receive the optical signal from the first latchable asymmetric coupler and has a second tap output that receives a selected and alterable second fraction of the optical signal incident at the second latchable. In certain embodiments the first and second couplers are capable of operating at any of at least three tapping fractions.

A large-scale single-photonics-based optical switching system that occupies an area larger than the maximum area of a standard step-and-repeat lithography reticle is disclosed. The system includes a plurality of identical switch blocks, each of is formed in a different reticle field that no larger than the maximum reticle size. Bus waveguides of laterally adjacent switch blocks are stitched together at lateral interfaces that include a second arrangement of waveguide ports that is common to all lateral interfaces. Bus waveguides of vertically adjacent switch blocks are stitched together at vertical interfaces that include a first arrangement of waveguide ports that is common to all vertical interfaces. In some embodiments, the lateral and vertical interfaces include waveguide ports having waveguide coupling regions that are configured to mitigate optical loss due to stitching error.

In some examples, a mechanical transfer ferrule based optical switch may include an optical fiber tube unit connectable to an end of an optical fiber. The optical fiber tube unit may include a lens to transmit light through the optical fiber. An optical fiber tube unit positioning assembly may include an optical fiber tube unit support detachably connectable to the optical fiber tube unit, and an optical fiber tube unit guide to operatively position the optical fiber tube unit support relative to a multi-fiber connector. The optical fiber tube unit guide may align the optical fiber tube unit and the lens to a specified lens of the multi-fiber connector, and connect the optical fiber to a specified optical fiber channel.

A passive self-alignment fiber-to-fiber optical device is provided. The device includes a silicon base, a fiber alignment region, and an actuation region. When the device is configured as a fiber optical attenuator, displacement of a plunger in the actuation region alters the alignment of two optical fibers in the fiber alignment region, thereby varying the optical intensity between the two fibers. A series of beams in the actuation region successively reduces an initial displacement of a first beam to a smaller displacement of the plunger. When the device is configured as an optical switch, displacement of the plunger in the actuation region displaces the first optical fiber from a first position in alignment with the second optical fiber into a second position in alignment with a third optical fiber.

A fiber-optic switching system is provided which includes an optical fiber switch having first and second optical fiber portions and an electrically-controlled actuator. The first and second optical fiber portions are spaced apart with a gap between the portions that is sized to allow for light signal coupling between the optical fiber portions in a signal-passing state of the switch. The electrically-controlled actuator is coupled to transition the switch between the signal-passing state, where the light signal is allowed to pass between the optical fiber portions, and a signal-non-passing state, where the light signal is prevented from passing between the optical fiber portions. The electrically-controlled actuator includes an electroactive material exhibiting a physical change with change in an applied electrical field, where the physical change facilitates transitioning the optical fiber switch between the signal-passing and the signal-non-passing states.

A fiber optic strand distribution system utilizing a fiber optic reconfiguration robot moving in xyz directions within a fiber interconnect zone. The system includes a multiplicity of substantially equal length, substantially straight-line fiber strands in an x-z plane within the fiber interconnect zone; each fiber strand having a fixed, central point that lies in proximity to adjacent fiber strands at a distal end located within a linear, central backbone oriented parallel to a y axis; and each fiber strand having a moveable endpoint at a proximal end when engaged by the reconfiguration robot, wherein said moveable endpoint it is moveable between rearrangeable terminal locations along a partial spherical surface that is substantially equidistant from a midpoint of the linear, central backbone, and wherein the robot carries the moveable endpoint of the fiber strand according to a non-repeating braid algorithm and between terminal locations.

Wavelength division multiplexing (WDM) has enabled telecommunication service providers to fully exploit the transmission capacity of optical fibers. State of the art systems in long-haul networks now have aggregated capacities of terabits per second. Moreover, by providing multiple independent multi-gigabit channels, WDM technologies offer service providers with a straight forward way to build networks and expand networks to support multiple clients with different requirements. In order to reduce costs, enhance network flexibility, reduce spares, and provide re-configurability many service providers have migrated away from fixed wavelength transmitters, receivers, and transceivers, to wavelength tunable transmitters, receivers, and transceivers as well as wavelength dependent add-drop multiplexer, space switches etc. However, to meet the competing demands for improved performance, increased integration, reduced footprint, reduced power consumption, increased flexibility, re-configurability, and lower cost it is desirable to exploit/adopt monolithic optical circuit technologies, hybrid optoelectronic integration, and microelectromechanical systems (MEMS).

A nano-opto-electro-mechanical System (NOEMS) phase shifter is described. The NOEMS may include a multi-slot waveguide structure suspended in air. The multi-slot waveguide structure may include three or more waveguides separated from each other by slots. The width of the slots may be sufficiently small to support slot modes, where a substantial portion of the mode energy is within the slots. For example, the slots may have widths less than 200 nm or less than 100 nm. The multi-slot waveguide structure may be disposed in a trench formed though the upper cladding of a substrate. An undercut may be formed under the multi-slot waveguide structure to enable free motion of the structure. NOEMS phase modulators of the types described herein may be used in connection with photonic processing systems, telecom/datacom systems, analog systems, etc.

Apparatus for establishing optical connection between optical fibers, the apparatus comprising: a first array comprising a plurality of slack management units (SMU), each having a holding socket for holding an optical end connector of an optical fiber and configured to reel in a length of fiber released when the optical end connector is removed from the holding socket; a second array comprising a plurality of coupling sockets, each configured to hold an optical end of an optical fiber; and a pick and place grabber controllable to grab an optical end connector seated in a holding socket of any SMU in the first array, move the optical end connector into any coupling socket in the second array to establish an optical connection between the optical fiber connected to the optical end connector, and an optical end of an optical fiber held in the coupling socket; at least one identification (ID) tag; an ID reader operable to interrogate each of the at least one ID tag; a controller configured to control the ID reader to interrogate an ID tag of the at least one ID to identify an optical end connector in the first array and/or a coupling socket in the second array.