Systems and methods for a scalable Open Shortest Path First (OSPF) deployment for optical networks include steps of causing communication to a router connected to a data communication network, for North-South communication; causing communication to a management plane associated with the optical network via one or more interfaces that are each connected to one or more Open Shortest Path First (OSPF) domains, for East-West communication; and implementing an OSPF terminator between the one or more OSPF domains that includes receiving OSPF packets, sending self-generated OSPF packets, and preventing flooding of received OSPF packets between the one or more OSPF domains.

The present disclosure provides a method for dynamically allocating an optical channel. The method includes receiving a user input request from a user. In addition, the method includes receiving an OLS spectrum data of the optical channel. Further, the method includes computing one or more configuration parameters for a predefined pair of transponders of one or more transponders based on the user input request and the OLS spectrum data. Furthermore, the method includes configuring the one or more configuration parameters on the predefined pair of transponders of the one or more transponders. Moreover, the user is associated with the one or more transponders. The user input request is associated with the predefined pair of transponders of the one or more transponders. The user input request includes parameters for the optical channel allocation on the predefined pair of transponders.

An apparatus includes a first reconfigurable optical add/drop multiplexer (ROADM) to receive a first optical signal and a second ROADM to receive a second optical signal. The apparatus also includes a reconfigurable optical switch that includes a first switch, switchable between a first state and a second state, to transmit the first optical signal at the first state and block the first optical signal at the second state. The reconfigurable optical switch also includes a second switch, switchable between the first state and the second state, to transmit the second optical signal at the first state and block the second optical signal at the second state. The reconfigurable optical switch also includes an output port to transmit an output signal that is a sum of possible optical signals transmitted through the first switch and the second switch.

A first optical node is configured for deployment in an optical network including second optical nodes having a ring topology. The first optical node includes an optical encoder and a decoder. The optical encoder is configured to form a third optical signal for transmission into the optical network by combining a first optical signal generated by the first optical node with a second optical signal received by the first optical node from the second optical nodes. The decoder is configured to extract information from fourth optical signals received from the second optical nodes. In some cases, the first optical node includes a receive buffer configured to store information representative of the fourth optical signals received from the second optical nodes and a transmit buffer configured to store information used to generate the first optical signal.

A system for in-service defragmentation may identify optical signals having wavelengths within a first predefined optical wavelength band for transition from a current channel to an alternate channel within the first band and may determine directions and amounts by which to move the wavelengths. The identified wavelengths in the first band may be slowly and deliberately drifted by the determined amounts, using multiple incremental adjustments, and converted to corresponding wavelengths in a second predefined optical wavelength band for transmission. During the transitions, the drifting optical signals in the second band may be combined with optical signals remaining in their current channels in the first band for transmission. Once the wavelength transitions are complete, the transitioned optical signals may be transmitted on their alternate channels in the first band. Collections of wavelength transitions that do not cross each other may be identified and may be performed substantially in parallel.

Systems and methods are provided for enabling degree-to-degree protection within an optical node, such as an Optical Add/Drop Multiplexer (OADM) node or Reconfigurable Optical Add/Drop Multiplexer (ROADM) node. According to an exemplary protection method, a step is executed for configuring two degree-to-degree fiber links between a first degree of the OADM node and a second degree of the OADM node. The method also includes designating a first degree-to-degree fiber link of the two degree-to-degree fiber links as a primary fiber link. Also, the method includes designating a second degree-to-degree fiber link of the two degree-to-degree fiber links as a protection fiber link configured for providing protection if a fiber break is detected on the primary fiber link.

A pluggable electric connector can communicate a communication data signal and a control signal with an optical communication device. An optical signal output unit is configured to be capable of selectively output a wavelength of an optical signal. An optical power adjustment unit can adjust optical power of the optical signal. A pluggable optical receptor can output the optical signal to an optical fiber. A control unit controls a wavelength change operation according to the control signal. The control unit, according to a wavelength change command, commands the optical power adjustment unit to block output of the optical signal, commands the light signal output unit to change the wavelength of the optical signal after the optical signal is blocked, and commands the light signal output unit and the optical power adjustment unit to output the optical signal after the wavelength change operation.

A software-defined network multi-layer controller (SDN-MLC) may communicate with multiple layers of a telecommunication network. The SDN-MLC may have an optimization algorithm that helps manage, in near real-time, the multiple layers of the telecommunication network.

A transmitting apparatus includes: a first processor circuit; a second processor circuit; a modulation circuit; and a switch circuit, wherein the first processor circuit is configured to execute a generating process that includes mapping each of a plurality of bit strings to a symbol in predetermined order for each number of bits according to a multivalued degree of a multilevel modulation method, and generating a symbol information piece according to the symbol, wherein the modulation circuit is configured to modulate light in accordance with the symbol information piece based on the multilevel modulation method; wherein the second processor circuit is configured to execute a detecting process that includes detecting each of inputs of a plurality of data signals, wherein the switch circuit is configured to select the plurality of bit strings based on a detection result of inputs of the plurality of data signals,

An optical node includes one or more Optical Add/Drop Multiplexer (OADM) devices which each form a respective degree connected to an associated Optical Multiplex Section (OMS) section of a cascaded optical network including a plurality of OMS sections; and a channel holder source connected to the OADM devices, wherein the OADM device is configured to detect a local fault affecting one or more traffic signals and switch to the channel holder source to provide a respective channel holder the one or more traffic signals with a same power level and spectral location such that the respective channel holder replaces a respective traffic signal at the OADM device which is a first switching port after the fault and such that all other OADM devices at other optical nodes downstream from the fault remain switched to the one or more traffic signals due to a presence of the provided respective channel holder.