One example may include transmitting data between a client device and a server over a first channel, identifying a transmission rate of the first channel, transmitting additional data between the client device and the server over a second channel, determining whether a transmission rate of the second channel is above or below a transmission rate threshold associated with the first channel, and bonding the first channel with the second channel based on the transmission rate of the second channel being above the transmission rate threshold.

A wireless communication system with scalable diversity and multi-transceiver diversity deployment is disclosed. An example communication system includes a first wireless transceiver, having a first bandwidth and a first center frequency, a second transceiver, having a second bandwidth and a second center frequency, and a processor. The processor is configured to operate the wireless communication system in a first mode when a difference between the first center frequency and the second center frequency is greater than or equal to half of the first bandwidth plus the second bandwidth. The processor is also configured to operate the wireless communication system in a second mode when a difference between the first center frequency and the second center frequency is less than half of the first bandwidth plus the second bandwidth.

A method and apparatus for maintaining network connectivity over power lines is disclosed. Such network connectivity is maintained even if various customers are covered by different power line networks or if one or more power lines in a network are unavailable to transmit data. More particularly, in order to bridge a gap in a power line network, one or more messages are extracted from a first node in a power line network and are then transmitted to a second node via free space transmission. When those messages are received at the second node, the message is injected back into the power line on the other side of a gap in power line coverage. This method of transmission backup will continue until power line connectivity is restore upon which the preferred method will be selected and used.

A method and apparatus for maintaining network connectivity over power lines is disclosed. Such network connectivity is maintained even if various customers are covered by different power line networks or if one or more power lines in a network are unavailable to transmit data. More particularly, in order to bridge a gap in a power line network, one or more messages are extracted from a first node in a power line network and are then transmitted to a second node via free space transmission. When those messages are received at the second node, the message is injected back into the power line on the other side of a gap in power line coverage. This method of transmission backup will continue until power line connectivity is restore upon which the preferred method will be selected and used.

Redundancy architectures for communications systems are provided. An example redundancy architecture includes a plurality of active radio-frequency (RF) hardware units, one or more RF signal splitters configured to couple a plurality of RF input signals to the plurality of active RF hardware units, and one or more RF signal combiners configured to couple RF signals processed by the plurality of active RF hardware units to a plurality of RF output paths. The one or more RF signal splitters are configured to split each RF input signal of the plurality of RF input signals into multiple copies of the RF input signal, and to provide each copy of the multiple copies of the RF input signal to a different one of the plurality of active RF hardware units. The one or more RF signal combiners are configured to combine the multiple copies of the RF input signals into RF output signals.

Redundancy architectures for communications systems are provided. An example redundancy architecture includes a plurality of active radio-frequency (RF) hardware units, one or more RF signal splitters configured to couple a plurality of RF input signals to the plurality of active RF hardware units, and one or more RF signal combiners configured to couple RF signals processed by the plurality of active RF hardware units to a plurality of RF output paths. The one or more RF signal splitters are configured to split each RF input signal of the plurality of RF input signals into multiple copies of the RF input signal, and to provide each copy of the multiple copies of the RF input signal to a different one of the plurality of active RF hardware units. The one or more RF signal combiners are configured to combine the multiple copies of the RF input signals into RF output signals.

The disclosure includes systems and methods for the analysis, comparison, and selection between multiple redundant data streams. The data streams may be analyzed, compared, and/or selected based on the individual number of consecutive data frame losses in a data stream, the number of channel noise errors over a time period in a data stream, the clock synchronization values associated with a data stream, the traversal time of a data stream, and/or a MAC address associated with a data stream.

The disclosure includes systems and methods for the analysis, comparison, and selection between multiple redundant data streams. The data streams may be analyzed, compared, and/or selected based on the individual number of consecutive data frame losses in a data stream, the number of channel noise errors over a time period in a data stream, the clock synchronization values associated with a data stream, the traversal time of a data stream, and/or a MAC address associated with a data stream.

In some embodiments, a first computing device detects a loss of a connection to a first source of timing information that the first computing device and a second computing device use to maintain synchronization with a first clock and a second clock. The first computing device receives a second source of timing information from the second computing device. The second source of timing information is also being transmitted to a third computing device. The first computing device uses the second source of timing information to determine a first timestamp and determines a second timestamp from the first clock. The first computing device uses the first timestamp and the second timestamp to adjust a rate of the first clock where the first clock is used to transmit the second source of timing information from the second computing device to the third computing device.

Systems and methods are described for paired-beam satellite communications in a flexible satellite architecture. Embodiments include one or more bent pipe satellites having multiple transponders for servicing a number of spot beams. Implementations include novel types of paired-beam transponders that communicatively couple gateway terminals and user terminals in different spot beams. Some implementations also include loopback transponders that communicatively couple gateway terminals and user terminals in the same spot beam. The transponders can use similar components, can provide for flexible forward-link and return-link spectrum allocation, and/or can provide other features. Certain embodiments further include support for utility gateway terminal service and/or redundancy (e.g., active spares) for one or more active components.