Abstract: A wireless hoist system including a first hoist device having a first motor and a first wireless transceiver and a second hoist device having a second motor and a second wireless transceiver. The wireless hoist system includes a controller in wireless communication with the first wireless transceiver and the second wireless. The controller is configured to receive a user input and determine a first operation parameter and a second operation parameter based on the user input. The controller is also configured to provide, wirelessly, a first control signal indicative of the first operation parameter to the first hoist device and provide, wirelessly, a second control signal indicative of the second operation parameter to the second hoist device. The first hoist device operates based on the first control signal and the second hoist device operates based on the second control signal.

Abstract: A method and system for providing secure aerial or space communications. A general payload and a hosted payload are provided on a vehicle. The hosted payload encrypts a data packet that contains restricted data using a secure key to create an encrypted packet. The general payload encrypts the encrypted packet using a general key to create a multilayer-encrypted packet. The multilayer-encrypted packet is transmitted from the vehicle to a destination.

Abstract: A system and method for an adaptive network of network access nodes comprises a global network operations center (GNOC) receiving operator inputs and generating a global policy according to the operator inputs. The GNOC and/or a distributed network gateway (GW) generate configuration commands for configurations for at least one of the network access nodes based on the global policy, transmit the configuration commands to at least one of the network access nodes, and receive telemetry from at least one of the network access nodes. The distributed network GW transmits a summary of key performance indicators (KPIs) to the GNOC and the GNOC revises the global policy according to the summary of KPIs.

Abstract: A system and method for an adaptive network of network access nodes comprises a global network operations center (GNOC) receiving operator inputs and generating a global policy according to the operator inputs. The GNOC and/or a distributed network gateway (GW) generate configuration commands for configurations for at least one of the network access nodes based on the global policy, transmit the configuration commands to at least one of the network access nodes, and receive telemetry from at least one of the network access nodes. The distributed network GW transmits a summary of key performance indicators (KPIs) to the GNOC and the GNOC revises the global policy according to the summary of KPIs.

Abstract: A system and method for communicating data is disclosed. The system comprises a plurality of modems for receiving uplink data and transmitting downlink data; a switch, communicatively coupled to a plurality of MODEMs, the switch comprising a plurality of data queues, the switch for switchably accepting uplink data from the plurality of MODEMs and switchably providing downlink data from the plurality of data queues to the plurality of MODEMs; and a controller, communicatively coupled to the plurality of MODEMs and the switch, the controller for providing controller information for dynamically controlling the switch to switchably accept the uplink data from the plurality of MODEMs and to switchably provide downlink data from the plurality of data queues to the one or more of the plurality of MODEMs on a per-terminal and a per-communications link basis.

Abstract: Systems, methods, and apparatus for an adaptive self-optimizing network using closed-loop feedback are disclosed. A method for an adaptive network of network access nodes comprises a global network operations center (GNOC) receiving operator inputs and generating a global policy according to the operator inputs. The method further comprises the GNOC and/or a distributed network gateway (GW) generating configuration commands for configurations for at least one of the network access nodes based on the global policy, transmitting the configuration commands to at least one of the network access nodes, and receiving telemetry from at least one of the network access nodes. Also, the method comprises the distributed network GW transmitting a summary of key performance indicators (KPIs) to the GNOC. Further, the method comprises the GNOC revising the global policy according to the summary of KPIs.

Abstract: A system and method for communicating data is disclosed. The system comprises a plurality of modems for receiving uplink data and transmitting downlink data; a switch, communicatively coupled to a plurality of MODEMs, the switch comprising a plurality of data queues, the switch for switchably accepting uplink data from the plurality of MODEMs and switchably providing downlink data from the plurality of data queues to the plurality of MODEMs; and a controller, communicatively coupled to the plurality of MODEMs and the switch, the controller for providing controller information for dynamically controlling the switch to switchably accept the uplink data from the plurality of MODEMs and to switchably provide downlink data from the plurality of data queues to the one or more of the plurality of MODEMs on a per-terminal and a per-communications link basis.

Abstract: A software defined network including a constellation of software defined satellites. Each software defined satellite includes computing resources that are dynamically configurable to provide at least one of a plurality of different types of services. Each software defined satellite further includes an interface that interfaces with a software defined network ground station.

Abstract: A system and method for an adaptive network of network access nodes comprises a global network operations center (GNOC) receiving operator inputs and generating a global policy according to the operator inputs. The GNOC and/or a distributed network gateway (GW) generate configuration commands for configurations for at least one of the network access nodes based on the global policy, transmit the configuration commands to at least one of the network access nodes, and receive telemetry from at least one of the network access nodes. The distributed network GW transmits a summary of key performance indicators (KPIs) to the GNOC and the GNOC revises the global policy according to the summary of KPIs.

Abstract: A method and system for providing secure aerial or space communications. A general payload and a hosted payload are provided on a vehicle. The hosted payload encrypts a data packet that contains restricted data using a secure key to create an encrypted packet. The general payload encrypts the encrypted packet using a general key to create a multilayer-encrypted packet. The multilayer-encrypted packet is transmitted from the vehicle to a destination.

Abstract: A system includes a first MODEM configured to generate a first data packet (including a first virtual routing and forwarding (VRF) instance identifier associated with a first service, a first user group, or both) based on a first radio-frequency (RF) signal and a second MODEM configured to generate a second data packet (including a second VRF instance identifier associated with a second service, a second user group, or both) based on a second RF signal. The system includes a network device configured to receive the first data packet, transmit a first packet (including a first header that includes a first indicator associated with a first VRF instance) to a first device via a network, receive the second data packet, and transmit a second packet (including a second header that includes a second indicator associated with a second VRF instance) to a second device via the network.

Abstract: A system includes a first MODEM configured to generate a first data packet (including a first virtual routing and forwarding (VRF) instance identifier associated with a first service, a first user group, or both) based on a first radio-frequency (RF) signal and a second MODEM configured to generate a second data packet (including a second VRF instance identifier associated with a second service, a second user group, or both) based on a second RF signal. The system includes a network device configured to receive the first data packet, transmit a first packet (including a first header that includes a first indicator associated with a first VRF instance) to a first device via a network, receive the second data packet, and transmit a second packet (including a second header that includes a second indicator associated with a second VRF instance) to a second device via the network.

Abstract: A software defined network including a constellation of software defined satellites. Each software defined satellite includes computing resources that are dynamically configurable to provide at least one of a plurality of different types of services. Each software defined satellite further includes an interface that interfaces with a software defined network ground station.

Abstract: A satellite payload system is presented. The system includes plurality of optical processing modules, including a plurality of ring-connected optical processing modules and at least one inter-satellite optical processing module, and at least one optical fiber ring communicatively coupled to each of the ring-connected optical processing modules. At least one of the ring-connected optical processing modules is configured to provide on-board signal processing of signals conveyed on the at least one optical fiber ring. At least one of the ring-connected optical processing modules is communicatively coupled to a respective inter-satellite optical processing module. Each inter-satellite optical processing module is configured to optically communicatively couple to a respective remote satellite.

Abstract: A satellite payload system is presented. The system includes plurality of optical processing modules, including a plurality of ring-connected optical processing modules and at least one inter-satellite optical processing module, and at least one optical fiber ring communicatively coupled to each of the ring-connected optical processing modules. At least one of the ring-connected optical processing modules is configured to provide on-board signal processing of signals conveyed on the at least one optical fiber ring. At least one of the ring-connected optical processing modules is communicatively coupled to a respective inter-satellite optical processing module. Each inter-satellite optical processing module is configured to optically communicatively couple to a respective remote satellite.

Abstract: Systems, methods, and apparatus for an adaptive self-optimizing network using closed-loop feedback are disclosed. A method for sharing network resources comprises receiving, by a network operations center (NOC), user demand for users from an external network. The method further comprises receiving, by the NOC, key performance indicators from at least one internal network. Also, the method comprises determining, by the NOC, whether at least one internal network has available resources by analyzing the key performance indicators and the user demand. Further, the method comprises allowing, by the NOC when the NOC determines that there are available resources, at least some of the users from the external network to connect to at least one internal network according to the available resources.

Abstract: Systems, methods, and apparatus for an adaptive self-optimizing network using closed-loop feedback are disclosed. A method for sharing network resources comprises receiving, by a network operations center (NOC), access requests for users subscribed to an external network. The method further comprises receiving, by the NOC, a summary of key performance indicators from at least one internal network. Also, the method comprises determining, by the NOC, whether at least one internal network has available resources by analyzing the summary of key performance indicators and user demand from the access requests. Further, the method comprises allowing, by the NOC when the NOC determines that there are available resources, at least some of the users from the external network to connect to at least one internal network according to the available resources.

Abstract: Systems, methods, and apparatus for mobile routing for non-geostationary orbit (NGSO) systems using virtual routing areas (VRAs) are disclosed. A disclosed method comprises generating a plurality of routing graphs for each of a plurality of VRAs. Each of the routing graphs is for a different period of time, and comprises a gateway and satellites that are within view of each other and of the gateway during the period of time associated with the routing graph. The method further comprises generating at least one time-sliced graph for each of the routing graphs, where each of the time-sliced graphs shows connectivity between at least some of the satellites, which are on the routing graph associated with the time-sliced graph, with each other. Further, the method comprises, during each of the periods of the time, establishing communications between the satellites according to each of the time-sliced graphs for the period of time.

Abstract: Systems, methods, and apparatus for an adaptive self-optimizing network using closed-loop feedback are disclosed. A method for an adaptive network of network access nodes comprises a global network operations center (GNOC) receiving operator inputs and generating a global policy according to the operator inputs. The method further comprises the GNOC and/or a distributed network gateway (GW) generating configuration commands for configurations for at least one of the network access nodes based on the global policy, transmitting the configuration commands to at least one of the network access nodes, and receiving telemetry from at least one of the network access nodes. Also, the method comprises the distributed network GW transmitting a summary of key performance indicators (KPIs) to the GNOC. Further, the method comprises the GNOC revising the global policy according to the summary of KPIs.

Abstract: Systems, methods, and apparatus for an adaptive self-optimizing network using closed-loop feedback are disclosed. A method for sharing network resources comprises receiving, by a network operations center (NOC), access requests for users subscribed to an external network. The method further comprises receiving, by the NOC, a summary of key performance indicators from at least one internal network. Also, the method comprises determining, by the NOC, whether at least one internal network has available resources by analyzing the summary of key performance indicators and user demand from the access requests. Further, the method comprises allowing, by the NOC when the NOC determines that there are available resources, at least some of the users from the external network to connect to at least one internal network according to the available resources.