In an optical network having a terrestrial terminal and an open cable interface (OCI) connecting a submarine cable to a terrestrial cable, the OCI may include a filter positioned on an optical path between the terrestrial cable and the submarine cable and configured to pass first communication signals of a first frequency band, and filter out secondary signals of a second frequency band that does not overlap with the first frequency band. The secondary signals may be looped back to the terrestrial terminal. The terrestrial terminal may detect the looped back secondary signals, and in response, determine the presence of the OCI and that the supervisory signals were rerouted by the OCI.

Margin hedging in optical communication systems allows for overhead within the optical system. A machine learning model can be trained using the output of a physics based simulation of the optical system as well as the features of the optical system. A trained machine learning model can adjust the results of a physics based simulation of an optical network to more accurately match the adjusted simulation results to the “true” performance of the optical network. The margins of the optical communication system can be more tailored to the true performance of a designed or planned optical system.

This application discloses a service data processing method and device. A transmit-end device may generate an optical transport network (OTN) encapsulated signal carrying service data, and generate at least n FlexO (flexible optical transport network) frames based on the OTN encapsulated signal and send the at least n FlexO frames, where r FlexO frames in the at least n FlexO frames carry service check data, and the service check data may be used to restore the service data when bit error rates of k FlexO frames are greater than a reference bit error rate. In this way, if no more than r physical ports included in a FlexO group interface fail, or a bit error rate of no more than r FlexO frames is greater than the reference bit error rate due to another reason, a receive-end device may restore the service data through a received FlexO frame.

This application discloses a service data processing method and device. A transmit-end device may generate an optical transport network (OTN) encapsulated signal carrying service data, and generate at least n FlexO (flexible optical transport network) frames based on the OTN encapsulated signal and send the at least n FlexO frames, where r FlexO frames in the at least n FlexO frames carry service check data, and the service check data may be used to restore the service data when bit error rates of k FlexO frames are greater than a reference bit error rate. In this way, if no more than r physical ports included in a FlexO group interface fail, or a bit error rate of no more than r FlexO frames is greater than the reference bit error rate due to another reason, a receive-end device may restore the service data through a received FlexO frame.

A Wireless Optical Network Terminal (WONT) includes an interior connection module having an interior communication module having a transceiver configured with technology to enable data to be transferred wirelessly through building materials, a resonance power transmitter, and a connector configured to connect the interior communication module and the resonance power transmitter to a power supply. The WONT further includes an exterior connection module having an exterior communication module having a transceiver configured with a same technology to enable data to be transferred wirelessly through building materials as is present in the interior communication module, a resonance power receiver configured to provide power to the exterior communication module, and a connector configured to permit the exterior connection module to be an optical network terminal (ONT) of a passive optical network (PON).

A Wireless Optical Network Terminal (WONT) includes an interior connection module having an interior communication module having a transceiver configured with technology to enable data to be transferred wirelessly through building materials, a resonance power transmitter, and a connector configured to connect the interior communication module and the resonance power transmitter to a power supply. The WONT further includes an exterior connection module having an exterior communication module having a transceiver configured with a same technology to enable data to be transferred wirelessly through building materials as is present in the interior communication module, a resonance power receiver configured to provide power to the exterior communication module, and a connector configured to permit the exterior connection module to be an optical network terminal (ONT) of a passive optical network (PON).

The present invention provides a method for controlling a connection between an ONU and an OLT, wherein the method includes the steps of: (a) downloading an OMCI message from the OLT; (b) enabling an OMCI management program to process the OMCI message to try to generate a plurality of models; (c) if the plurality of models are not successfully generated by using the OMCI management program to process the OMCI message, modifying the OMCI management program to generate a modified OMCI management program when the ONU is not connected with the OLT; and (d) using the modified OMCI management program to process the OMCI message to try to generate the plurality of models.

The present invention provides a method for controlling a connection between an ONU and an OLT, wherein the method includes the steps of: (a) downloading an OMCI message from the OLT; (b) enabling an OMCI management program to process the OMCI message to try to generate a plurality of models; (c) if the plurality of models are not successfully generated by using the OMCI management program to process the OMCI message, modifying the OMCI management program to generate a modified OMCI management program when the ONU is not connected with the OLT; and (d) using the modified OMCI management program to process the OMCI message to try to generate the plurality of models.

Aspects of the disclosure provide for determining a network configuration. For instance, a system may include a controller including one or more processors. The one or more processors may be configured to receive information from each of a plurality of available nodes within a network, the plurality of available nodes including at least one aerial vehicle; determine a plurality of constraints for a future point in time, each one of the plurality of constraints including one or more minimum service requirements for a geographic area; attempt to determine a first network configuration for each of the plurality of available nodes that satisfies all of the constraints; when unable to determine the first network configuration, determine a second network configuration for the plurality of available nodes and at least one additional ground-based node that satisfies all of the constraints; and send instructions in order to affect the second network configuration.

Aspects of the disclosure provide for determining a network configuration. For instance, a system may include a controller including one or more processors. The one or more processors may be configured to receive information from each of a plurality of available nodes within a network, the plurality of available nodes including at least one aerial vehicle; determine a plurality of constraints for a future point in time, each one of the plurality of constraints including one or more minimum service requirements for a geographic area; attempt to determine a first network configuration for each of the plurality of available nodes that satisfies all of the constraints; when unable to determine the first network configuration, determine a second network configuration for the plurality of available nodes and at least one additional ground-based node that satisfies all of the constraints; and send instructions in order to affect the second network configuration.