Abstract: An approach is provided for delivering high throughput inroute bandwidth to a terminal in a shared bandwidth satellite communications system. A backlog level of each of a number of remote terminals is monitored, wherein the backlog level of each terminal reflects an amount of data traffic awaiting transmission via an inroute channel of the communications system. When it is determined that the backlog level of one terminal meets a first threshold level, the terminal is assigned to an express priority bandwidth allocation stage. The backlog level of the terminal is monitored while assigned to the express priority stage. When it is determined that the backlog level of the terminal has fallen below a second threshold level, the terminal is removed from the express priority stage. Further, a probability is applied to a qualifying terminal, where the probability controls whether the terminal is assigned to the express priority bandwidth stage.

Abstract: Systems and methods described herein are directed to techniques for selective TCP spoofing of a TCP connection between a first and a second host based on spoofing resource conditions and characteristics of the hosts involved in the TCP connection. In implementations, spoofing resource conditions may be based on a percentage of available resources in use by each of a TCP spoofer and a TCP spoofer peer. In implementations, characteristics of the hosts may be determined by tracking i) each TCP connection application type seen for each host over a time window; and ii) packet loss conditions of local hosts over a time window.

Abstract: A transmitter includes a buffer programmed to queue packets and a computing device having a processor and a data storage medium. The computing device is programmed to generate at least two sub-packets from each of the plurality of packets stored in the queue. For each sub-packet, the computing device is programmed to identify a plurality of transmission opportunities. Each transmission opportunity is associated with one of a plurality of networks. The computing device is further programmed to select among the plurality of transmission opportunities and transmit the sub-packet over the network associated with the selected transmission opportunity.

Abstract: In a telecommunication system, a gateway receives a first burst packet and a second burst packet, both encoded with a unique word associated with a color, a value, and an associated time slot. The gateway associates the second burst packet to the first burst packet based on the color and value associated with the unique word used to encode the second burst packet and a received time slot at which the second burst packet is received. A terminal generates the burst packets by generating the first burst packet with a group header and the second burst packet without the group header, encoding the first burst packet and the second burst packet with the unique word, and transmitting the encoded first burst packet and the encoded second burst packet to the gateway.

Abstract: A telecommunication system includes a gateway receiver having a processor and a data storage medium. The receiver is programmed to wirelessly communicate with a plurality of terminals, determine an error rate associated with communication with the plurality of terminals, determine an operating probability from the error rate, and transmit the operating probability to the plurality of terminals. A terminal includes a transmitter programmed to transmit signals to the gateway receiver in accordance with a number of transmitting slots. The terminal has a receiver programmed to receive signals transmitted from the gateway receiver, including an operating probability signal representing the operating probability. The terminal also includes processor programmed to select the number of transmitting slots based at least in part on the operating probability.

Abstract: A terminal device in a first network includes a processor programmed to receive first data indicating a respective first loading of each of a plurality of first level access devices. The processor is further programmed to select a first level access device based at least in part on the first data; and communicate with a second network via the selected first level access device and a selected second level access device. Each of the first level access devices is switchable to communicate with the first terminal via at least a respective one of one or more shared access channels, and each of a plurality second level access devices is switchable to communicatively couple one or more of the plurality of first level access devices with a second network.

Abstract: An approach for selective dynamic disabling of transport layer handshake spoofing is provided. A local proxy node of a communications network receives request message from a respective local host for establishing a network connection with a remote host. A destination address for the network connection is determined. It is determined whether the destination address is included in a handshake spoofing bypass list. If it is determined that the destination address is included in the spoofing bypass list, a corresponding un-spoofed connection request message is transmitted to a remote proxy node associated with the remote host, in accordance with a respective handshaking protocol for the connection establishment. If it is determined that the destination address is not included in the spoofing bypass list, a corresponding spoofed connection request message is transmitted to the remote proxy node, in accordance with a respective handshake spoofing protocol for the connection establishment.

Abstract: An approach for providing secure communication services is disclosed. A secure data tunnel from a source node to a destination node is established via a plurality of secure segments across a data communications network. A data path is established via the secure data tunnel, where the data path supports a performance enhancing mechanism that improves performance of data communications over the data path. The performance enhancing mechanism multiplexes data packet flows from the source node for transmission over the data path, and performs one or more of connection startup latency reduction, acknowledgment message spoofing, window sizing adjustment, compression and selective retransmission.

Abstract: A system for scheduling prioritized traffic in a scrambled and coded multiple access (SCMA) system multiple terminals and a gateway. Each terminal is configured to receive packets from user devices and place the packets on various input queues. The packets are en-queued onto a plurality of output queues based on priority or service class. The terminal is further configured to detect one or more available SCMA slots within a frame of a communication system, and de-queue packets from the highest priority output queue onto the frame via one or more SCMA bursts. The terminal includes transceiver for transmitting/receiving frames of the communication system to/from the gateway. The terminals autonomously transmit SCMA bursts on a first channel, and transmit TDMA bursts on a second channel based on assigned timings received from the gateway.

Abstract: An approach is provided for bandwidth allocation on a per terminal utilization and per inroute/inroute group basis, which optimizes bandwidth utilization. An aggregate average bandwidth usage of a plurality of remote terminals over a wireless communications channel is determined. A maximum rate for bandwidth allocations to each of the remote terminals for respective data transmissions over the channel is determined. A utilization metric reflecting a bandwidth utilization by one of the remote terminals for data transmissions over the channel is determined. An updated rate for bandwidth allocations to the one terminal is determined based on the utilization metric for the terminal, a target bandwidth utilization and tolerance range for the one terminal, and the maximum rate for the data allocations to each of the remote terminals. The updated rate for the bandwidth allocations to the one terminal is applied to subsequent bandwidth allocations for the one terminal.

Abstract: A system and method for association of remote nodes with respective aggregation nodes in a high capacity shared bandwidth communications network, is provided. A gateway receives an association request message from a terminal device, wherein the association request message includes a service signature and service parameters of the terminal device. The gateway determines whether the association request message reflects a valid request based on the service signature. The gateway determines service requirements of the terminal device, based on a correspondence between the service parameters and associated information of a service requirement database of the gateway. The gateway determines whether it is configured for servicing the service requirements of the terminal device. The gateway transmits an association accept message, including one or more association parameters.

Abstract: Approaches are provided for efficient bandwidth allocation for real-time service traffic flows, providing for assured QoS and efficient spectrum utilization. A terminal of a wireless communications network receives data from one or more associated interface devices. A snooper captures a session request message from one of the interface devices for initiation of a setup process to establish a communications session over the communications network, and parses the session request message to obtain associated session parameters. Inroute bandwidth requirements for the communications session are determined based on the session parameters. A bandwidth reservation process is initiated to obtain bandwidth allocations to satisfy the inroute bandwidth requirements.

Abstract: A system and method for association of remote nodes with respective aggregation nodes in a high capacity shared bandwidth communications network, which meets various requirements and desires associated with efficient, robust, reliable and flexible broadband services, and which is relatively efficient and automated from a network management and load balancing standpoint, is provided. A remote node receives a message transmitted by a gateway over the communications network, wherein the message includes service codes identifying one or more service capabilities of the gateway. The remote node determines, based on the service codes, whether the gateway is an eligible gateway for servicing one or more service requirements of the remote node. The remote node then adds the gateway to a pool of eligible gateways within the communications network.

Abstract: A transmitter includes a buffer programmed to queue packets and a computing device having a processor and a data storage medium. The computing device is programmed to generate at least two sub-packets from each of the plurality of packets stored in the queue. For each sub-packet, the computing device is programmed to identify a plurality of transmission opportunities. Each transmission opportunity is associated with one of a plurality of networks. The computing device is further programmed to select among the plurality of transmission opportunities and transmit the sub-packet over the network associated with the selected transmission opportunity.

Abstract: In a telecommunication system, a gateway receives a first burst packet and a second burst packet, both encoded with a unique word associated with a color, a value, and an associated time slot. The gateway associates the second burst packet to the first burst packet based on the color and value associated with the unique word used to encode the second burst packet and a received time slot at which the second burst packet is received. A terminal generates the burst packets by generating the first burst packet with a group header and the second burst packet without the group header, encoding the first burst packet and the second burst packet with the unique word, and transmitting the encoded first burst packet and the encoded second burst packet to the gateway.

Abstract: A telecommunication system includes a gateway receiver having a processor and a data storage medium. The receiver is programmed to wirelessly communicate with a plurality of terminals, determine an error rate associated with communication with the plurality of terminals, determine an operating probability from the error rate, and transmit the operating probability to the plurality of terminals. A terminal includes a transmitter programmed to transmit signals to the gateway receiver in accordance with a number of transmitting slots. The terminal has a receiver programmed to receive signals transmitted from the gateway receiver, including an operating probability signal representing the operating probability. The terminal also includes processor programmed to select the number of transmitting slots based at least in part on the operating probability.

Abstract: An approach for selective dynamic disabling of transport layer handshake spoofing is provided. A local proxy node of a communications network receives request message from a respective local host for establishing a network connection with a remote host. A destination address for the network connection is determined. It is determined whether the destination address is included in a handshake spoofing bypass list. If it is determined that the destination address is included in the spoofing bypass list, a corresponding un-spoofed connection request message is transmitted to a remote proxy node associated with the remote host, in accordance with a respective handshaking protocol for the connection establishment. If it is determined that the destination address is not included in the spoofing bypass list, a corresponding spoofed connection request message is transmitted to the remote proxy node, in accordance with a respective handshake spoofing protocol for the connection establishment.

Abstract: Approaches are provided for efficient bandwidth allocation for real-time service traffic flows, providing for assured QoS and efficient spectrum utilization. A terminal of a wireless communications network receives data from one or more associated interface devices. A snooper captures a session request message from one of the interface devices for initiation of a setup process to establish a communications session over the communications network, and parses the session request message to obtain associated session parameters. Inroute bandwidth requirements for the communications session are determined based on the session parameters. A bandwidth reservation process is initiated to obtain bandwidth allocations to satisfy the inroute bandwidth requirements.

Abstract: An approach is provided for delivering high throughput inroute bandwidth to a terminal in a shared bandwidth satellite communications system. A backlog level of each of a number of remote terminals is monitored, wherein the backlog level of each terminal reflects an amount of data traffic awaiting transmission via an inroute channel of the communications system. When it is determined that the backlog level of one terminal meets a first threshold level, the terminal is assigned to an express priority bandwidth allocation stage. The backlog level of the terminal is monitored while assigned to the express priority stage. When it is determined that the backlog level of the terminal has fallen below a second threshold level, the terminal is removed from the express priority stage. Further, a probability is applied to a qualifying terminal, where the probability controls whether the terminal is assigned to the express priority bandwidth stage.

Abstract: An approach is provided for bandwidth allocation on a per terminal utilization and per inroute/inroute group basis, which optimizes bandwidth utilization. An aggregate average bandwidth usage of a plurality of remote terminals over a wireless communications channel is determined. A maximum rate for bandwidth allocations to each of the remote terminals for respective data transmissions over the channel is determined. A utilization metric reflecting a bandwidth utilization by one of the remote terminals for data transmissions over the channel is determined. An updated rate for bandwidth allocations to the one terminal is determined based on the utilization metric for the terminal, a target bandwidth utilization and tolerance range for the one terminal, and the maximum rate for the data allocations to each of the remote terminals. The updated rate for the bandwidth allocations to the one terminal is applied to subsequent bandwidth allocations for the one terminal.