The present disclosure relates to a method, a medium, a program product, and a modem for setting modulation modes. The method includes detecting by a modem whether a modulation mode of the modem is inverted, the modem being capable of operating in a plurality of modulation modes, and each modulation mode having a different modulation order; and in response to the determination that the number of times of inversion of the modulation mode within a first predetermined time has reached a threshold, setting by the modem the modulation mode of the modem to a modulation mode other than a modulation mode with the highest modulation order in all modulation modes included in the inversion process and maintaining the set modulation mode for a second predetermined time. By the above method, the modulation mode is prevented from repeatedly inverting, thereby maintaining the downstream data throughput at a high level.

A cable distribution system includes a head end connected to a plurality of customer devices through a transmission network that includes a remote fiber node, that converts received data to analog data suitable to be provided on a coaxial cable for the plurality of customer devices. The plurality of vCores instantiated on at least one of servers is configured within a container to provide services to the plurality of customer devices through the transmission network, where each of the vCores includes a service endpoint that is accessible from within the container while each of the vCores does not include a service endpoint that is directly accessible from a network address exterior to the container. A gateway instantiated one of the servers within the container provides access to each of the vCores using said service endpoint over a non-encrypted channel, and provides access to the gateway from a network address exterior to the container over an encrypted channel.

A system may include primary and secondary integrated circuits. The primary integrated circuit may receive a first subset of data packets associated with a first set of sequence numbers. The secondary integrated circuit may receive a second subset of data packets associated with a second set of sequence numbers. The primary integrated circuit is configured to manage the first set of sequence numbers and the second set of sequence numbers on behalf of the secondary integrated circuit and for the system.

A method for operation of a broadband access network of a telecommunications network includes: in a first step, a program or configuration information is provided to or received by an orchestrator node or functionality; in a second step, subsequent to the first step, at least one piece of program or control information is provided or transmitted to at least one programmable network node; and in a third step, subsequent to the second step, the at least one piece of program or control information is activated to be executed by the at least one programmable network node.

The present invention is directed to a CATV & MoCA® device, such as a RF signal amplifier. The RF signal amplifier includes a RF input port to receive signals from, and transmit signals to, a service provider. The RF input port is connected to an active communication path with a downstream signal amplifier leading to an input of a resistive splitter network. The resistive splitter network has plural interconnected resistors, which split the amplified signal received at the input of the resistive splitter network and provide the signal to plural “CATV & MoCA®” output ports. Upstream CATV signals received by the “CATV & MoCA®” output ports are combined by the resistive splitter network and sent to the RF input port to be transmitted to the service provider. MoCA® signals received by any one of the “CATV & MoCA®” output ports are carried by the resistive splitter network to the other “CATV & MoCA®” output ports, and potentially to other “MoCA® only” ports of the RF signal amplifier.

A mapping engine is configured to rearrange a configuration of data on a plurality of data channels. Each of a set of upstream filters is configured to pass one or more selected input radio frequency signals. An input of each of a set of upstream demodulators is configurable to be coupled to a selected one of the upstream filters and an output of each upstream demodulator is coupled to the mapping engine. An input of each of a set of upstream modulators is coupled to the mapping engine. An upstream aggregator comprises one or more inputs and is configured to aggregate a plurality of upstream-bound radio frequency signals, each input being configurable to be coupled to at least one selected upstream filter of the set of upstream filters and a selected upstream modulator.

Systems and methods to support switching of virtual cores.

Performing distributed Remote PHY scheduling operations. A low latency scheduler is disposed within or in proximity to a Remote PHY node. Upon identifying that a particular data flow qualifies for processing by the low latency scheduler, the low latency scheduler performs upstream Remote PHY scheduling operations for the particular data flow using a one or more dedicated channels that are designated as low latency channels. The Remote PHY upstream scheduling operations define when data may be transmitted by a Cable Modem (CM) to a Converged Cable Access Platform (CCAP) Core. A centralized scheduler is also located at the CCAP Core. The centralized scheduler performs Remote PHY upstream scheduling operations for all data flows which have not been identified as qualifying for processing by the low latency scheduler.

An example method includes requesting a first spectrum channel authorization to utilize a first spectrum channel from a spectrum access system. The method further includes accepting a first spectrum channel authorization response to utilize the first spectrum channel from the spectrum access system. The method additionally includes receiving a first service request from a first computing device over the first spectrum channel. The method still further includes sending a first heartbeat message to the spectrum access system. The method furthermore includes receiving a first heartbeat response message from the spectrum access system. The method yet further includes sending a first service flow request from the broadband access network to accommodate the first service request.

Methods and apparatus for enhancing communication and performance for a device backhauled by a wireline communication network. In one embodiment, the device comprises a small-cell or other wireless base station that is backhauled by a DOCSIS system within a managed HFC network, and the method and apparatus enable enhanced communication between the small cell/base station and the backhaul network so as to support “rate matching” between the device to mitigate packet overflow or other issues. In one implementation, enhanced cable modem (CM) and base station devices coordinate to inform the base station of the modulation order (and/or other parameters related to transmission of the data destined for the base station on the backhaul) so that the base station can selectively invoke utilization of higher-order modulation and/or coding schemes, as well as spatial multiplexing or beamforming.