Abstract: A system and method for Time Division Multiplexing (TDM) a signal for a beam hopping relay including generating the signal by interleaving a first multi-variable length SuperFrames (VLSFs) with a second multi-VLSFs; and transmitting the signal to the beam hopping relay. In the method, the first multi-VLSFs includes at least one first VLSF, the second multi-VLSFs includes at least one second VLSF, each of the first multi-VLSFs has a duration of a first dwell period, each of the second multi-VLSFs has a duration of a second dwell period, each of the at least one first VLSF and each of the at least one second VLSFs includes at least one SuperFrame unit (SFU).

Abstract: An accelerator and system to provide a combined transport Wide-Area Network (WAN) transports. The accelerator includes a tunnel manager to maintain tunnels traversing each of the WAN transports; an inspector to perform packet and IP flow classification to set a respective classification metric for a downstream packet to be sent over the combined transport; a transport selector to select a preferred tunnel from the tunnels based on the respective classification metric of the downstream packet; and a sender to send the downstream packet over the preferred tunnel. In the accelerator, the WAN transports include a high latency satellite transport and a low latency transport, and a respective tunnel connects the accelerator to a peer accelerator via one of the WAN transports. The accelerator includes a receiver to receive upstream packets arriving over the combined transport and to forward the upstream packets to a user equipment.

Abstract: A system includes a terminal and a gateway. The terminal is programmed to identify, in received data, a signature of rogue data that includes at least a device identifier and an application identifier, and to transmit, via uplink to a satellite, the identified signature to a gateway. The gateway is programmed to block downlink data, upon determining that downlink data includes the received signature, and to broadcast the received signature to a second gateway.

Abstract: Data communications methods and systems for data packets transmitted via tunnel sessions. Satellite data communication system providing data communication services between two or more network node devices via a satellite or other data communication system are typically associated with round trip times that can cause delay in the exchange of data. Many conventional protocols, such as TCP, are not well designed for operating across links with such long delays. To address this and provide a more acceptable end-user experience, the system can include a common acceleration and optimization processor configured to provide various network acceleration and/or optimization functions and a tunnel processor configured to provide tunnel protocol-specific processing for multi-protocol encapsulated traffic.

Abstract: A method and system for service management of a complex network including: computing, at a computer, a weather impact score for geographic areas within a coverage area of a satellite; predicting, based on the weather impact score for each of the geographic areas, a degradation of at least one of the satellite links serving a respective geographic area; and sending a notification about the degradation. The method may include calculating, with a computer, a peak Quality of Service (QoS) for each of the satellite links; aggregating, for a duration, transmission errors to calculate an actual QoS for each of the satellite links; and displaying a drill-down dashboard comprising a color-code for each of the satellite links, wherein the color-code corresponds to a severity of a respective discrepancy between a respective peak QoS and a respective actual QoS of a respective satellite link.

Abstract: A satellite communications system includes both LEO and MEO satellites, a gateway node (GN) which includes a MEO-GN modem and a LEO-GN modem, and a user terminal (UT) which includes a MEO-UT modem and a LEO-UT modem. The MEO-GN modem transmits data communications to the UT via the MEO satellites. The MEO-UT modem receives the data communications from the MEO-GN modem. The MEO UT modem forwards control messages regarding the data communications received from the MEO-GN modem, via a control message tunnel, to the MEO-GN modem. Via the control message tunnel, (i) the MEO-UT modem provides the control messages to the UT-LEO modem, (ii) the LEO-UT modem transmits the control messages to the LEO-GN modem via the LEO satellites, and (iii) the LEO-GN modem provides the control messages to the MEO-GN modem.

Abstract: A method for wireless data communications over a network is provided. Data packets are intended for a first terminal configured for a first communications protocol. Further data packets are intended for a second terminal configured for a second communications protocol and for the first protocol. The data packets are formatted as data bursts in accordance with the first protocol for transmission over a network channel that is configured based on the first protocol. The further data packets are formatted as data bursts in accordance with the second protocol for transmission over the network channel, and for transmission at a higher throughput rate of the second protocol (not compatible with the first protocol). The data bursts of the first protocol are transmitted over the channel for receipt by the first terminal. The data bursts of the second protocol are transmitted over the channel for receipt by the second terminal.

Abstract: A method of switching from a first gateway within a plurality of first gateways to a second gateway in a network includes precaching configuration information on the second gateway, that is within the first gateways, prior to switch-over to the second gateway. The first gateway from which the second gateway is being switched is identified. The second gateway is configured in accordance with the configuration of the first gateway based on the precached configuration information prior to the switch-over to the second gateway. Data traffic from data applications using the network is replicated and sent to the first gateway and the second gateway. Bandwidths allocated to terminals in the network are frozen in association with the switch-over to the second gateway. The bandwidths allocated to the terminals in the network are unfrozen based at least in part on an indication of completion of the switch-over to the second gateway.

Abstract: A method is provided for interleaving frequency reuse plans of multiple satellites to form an aggregate frequency reuse cell plan. A first plurality of spot beams is generated by a first satellite for a first frequency reuse plan based on radio frequency (RF) spectrum bands. A second plurality of spot beams is generated by a second satellite for a second frequency reuse plan based on the RF spectrum bands. The first and second plurality of spot beams are interleaved to generate an aggregate frequency reuse cell plan. According to the aggregate frequency reuse plan, each of a first plurality of cells is covered by a combination of at least two of the plurality of spot beams of the first satellite, and each of a first plurality of cells is covered by a combination of at least two of the plurality of spot beams of the second satellite.

Abstract: A system comprises a modem, configured to transmit data modulated based on an intermediate frequency within one of a C, X, or Ku band, and a single-stage block-up converter having an input electrically coupled via one inter-facility link cable to the modem, and an output electrically coupled to a high-power amplifier. The single-stage block-up-converter is configured to up-convert the intermediate frequency to a satellite communication frequency within the Ka, Q, or V band.

Abstract: A method of switching from a first gateway within a plurality of first gateways to a second gateway in a network includes precaching configuration information on the second gateway, that is within the first gateways, prior to switch-over to the second gateway. The first gateway from which the second gateway is being switched is identified. The second gateway is configured in accordance with the configuration of the first gateway based on the precached configuration information prior to the switch-over to the second gateway. Data traffic from data applications using the network is replicated and sent to the first gateway and the second gateway. Bandwidths allocated to terminals in the network are frozen in association with the switch-over to the second gateway. The bandwidths allocated to the terminals in the network are unfrozen based at least in part on an indication of completion of the switch-over to the second gateway.

Abstract: An apparatus for establishing communication between a base station and different generation terminals includes a multi-protocol stack capable of processing user traffic received from different generation terminals. The apparatus also includes a common physical layer that receives user traffic from different generation terminals and identifies the generation of the terminal sending the user traffic. The user traffic is then processed and routed based on the terminal generation. Traffic can be prioritized across current and legacy terminal types based on a variety of factors.

Abstract: A monitoring tool to facilitate real-time system performance monitoring, fault detection, fault isolation, and fault remediation verification, wherein the monitoring tool is connected to each of a plurality of gateways within a network, including a request reporter module configured to record results of URL access requests from one or more end users, a processing module configured to calculate a set of metrics based on success and failure rates for each of the URL access requests recorded by the request reporter and distinguish between failures related to the network and failures unrelated to the network, and a consolidator module configured to organize and present the set of metrics into a format useable for monitoring the network.

Abstract: A receiver determines whether an outbound carrier frequency among a plurality of outbound carrier frequencies, as received, includes interference. Based at least in part on a result of the determining, a new outbound carrier frequency is selected for the receiver. Optionally, the receiver sends an interference report to a system controller.

Abstract: Various arrangements for adaptive modulation of terminal to satellite communications are presented herein. A terminal may access a feedback data structure to perform a lookup based on a power level received as feedback. Based on performing the lookup using the power level in the feedback data structure, the terminal may determine a type of modulation to be used. The terminal may transmit one or more data packets to the satellite using the determined type of modulation without changing communication channel or requesting permission via the satellite to change modulation.

Abstract: Systems and methods are described, and one method includes storing, storing, in association with a backup gateway resource, a first and second primary to backup (P2B) pairing coefficient, and a first and second backup to primary (B2P) pairing coefficient. The first and second P2B pairing coefficients correspond to a first and second P2B pairing, respectively. The first and second B2P pairing coefficients are indicative of a metric of switching from the backup GWR to the first and second primary GWRs. A respective unavailability metric is received from the first primary GWR, second primary GWR, respectively, and backup GWR. A P2B pairing is selected selecting, based at least partially on the first and second P2B pairing coefficients , and first and the second B2P pairing coefficients. Traffic is switched to the backup GWR from the one of the first primary and second primary GWR corresponding to the selected P2B pairing.

Abstract: A user terminal (UT) to transmit small amounts of data, the UT including: a packet including the data, where the packet is less than 128 bytes; a frequency synchronizer to synchronize a transmission frequency of an ASCMA return link connecting the UT with a satellite gateway; and an ASCMA transmitter to transmit, without acquiring timing synchronization with the satellite gateway from the UT, the packet modulated over the synchronized transmission frequency as an ASCMA waveform including a preamble to indicate a start of a transmission. Other embodiments of this aspect include corresponding computer systems, apparatus, and computer programs recorded on one or more computer storage devices, each configured to perform the actions of the methods.

Abstract: Some implementations of the disclosure are directed to a satellite terminal comprising: a modem; and a radio frequency unit (RFU) configured to amplify and frequency upconvert a transmit signal for transmission over an inroute channel of a satellite communications network, the RFU comprising: an input power meter configured to measure a first power level of an intermediate frequency (IF) signal transmitted from the modem to an input of the RFU; an upconverter configured to frequency upconvert the IF signal to obtain a radio frequency (RF) signal; and an output power meter configured to measure a second power level of the RF signal. By taking the readings from the input and output power meters of the RFU, one or more calibration related functions, including a determination of the power loss due to the IF cable or a determination of the upconverter's gain, may be automatically performed at the satellite terminal.

Abstract: Arrangements for optimizing bandwidth of a satellite communication link are presented. A first satellite gateway system may transmit a first data set to a satellite to be relayed by the satellite to a first instance of user equipment. A second satellite gateway system may transmit a second data set to the satellite to be relayed by the satellite to a second instance of user equipment. A satellite gateway management system may determine that the second satellite gateway system has greater available bandwidth. The satellite gateway management system may route a third data set to be transmitted to the first instance of user equipment to the second satellite gateway system. The second satellite gateway system may transmit the third data set and beam steering data to the satellite, such that the satellite targets a downlink spot beam on the first instance of user equipment.

Abstract: A method for balancing inroute traffic load that contains both guaranteed QoS and best effort traffic. Hierarchical grouping levels are defined with the lowest level corresponding to inroutes within the system. Certain levels have common symbol rates, modulation rates, or both. When a new terminal requires admission, it is assigned to entries in the different hierarchical levels so that the inroute traffic load across all levels are balanced. Terminals are admitted to inroutes based, in part, on their channel quality indicator. Inroute traffic load can periodically rebalance based on elapsed time or terminal redistribution.