A processing system may obtain values of carrier attributes for a new carrier to be deployed in a cellular network, obtain values of the carrier attributes and values of a configuration parameter for a plurality of existing carriers in the cellular network, and construct an attribute value matrix comprising the values of the carrier attributes for the plurality of existing carriers, where the attribute value matrix associates the carrier attributes to the plurality of existing carriers, apply a regression to a function associating the attribute value matrix to a vector of the values of the configuration parameter for the plurality of existing carriers to learn coefficients of the function, apply the coefficients to a vector comprising the values of the plurality of carrier attributes for the new carrier to generate a value of the configuration parameter for the new carrier, and apply the generated value to the new carrier.

A method for interfacing an information technology device with a gateway includes (1) receiving, at the gateway, first downlink data, and (2) steering the first downlink data from the gateway to a first information technology (IT) device via at least one of a first plurality of parallel data communication links between the first IT device and the gateway, according to a first steering policy.

An information handling system includes a publisher device and an offload device. Multiple subscriber devices are associated with the publisher device. The offload device communicates with the publisher device. The offload device receives a packet transmission from the publisher device, and translates a topic address of the packet transmission to multiple destination addresses. The offload device sends the packet transmission to each of the subscriber devices. Each of the subscriber devices is associated with a corresponding destination address of the multiple destination address. The offload device receives one or more acknowledgements from the subscriber devices, and combines the one or more acknowledgements into a composite completion message. The offload device sends the composite completion message to the publisher device.

Data transmission method and device are provided. The method includes: determining a portion of a plurality of links as dedicated link, and the other portion of the plurality of links as ordinary link, wherein the dedicated link is configured to transmit control frames which include ordinary control frames and dedicated control frames, and the ordinary link is configured to transmit data frames and ordinary control frames; determining links for control frames to be transmitted and data frames to be transmitted; and when the dedicated link or the ordinary link obtains a transmission opportunity, transmitting a control frame or a data frame at a head of a queuing list of the link. By configuring the dedicated link, transmission efficiency of the control frames may be improved, compatibility with existing systems is relatively good, and complexity of design is relatively low.

Methods executed by a processor element for providing data packets from a modem to an application processor in a computing device are disclosed. Exemplary implementations may reorder packets received by the modem from a plurality of parallel flows so as to provide to the application processor batches of packets from individual flows within the plurality of parallel flows.

This document discloses a solution for selecting a transmission direction in a cell. A method comprises: determining, by a controller associated with a cell of a cellular communication system, a traffic asymmetry metric for the cell, the traffic asymmetry metric representing asymmetry between uplink and downlink traffic in the cell; comparing, by the controller, the traffic asymmetry metric with a threshold; upon determining, by the controller on the basis of the comparison, that the traffic asymmetry metric is one of greater and lower than the threshold, selecting a first transmission direction for a time interval; upon determining, by the controller on the basis of the comparison, that the traffic asymmetry metric is the other one of greater and lower than the threshold, selecting for the time interval a second transmission direction different from the first transmission direction, wherein the second transmission direction is a nominal transmission direction determined as common to a cell cluster comprising the cell and a set of neighboring cells, and wherein the controller determines the nominal transmission direction on the basis of traffic condition metrics acquired for the cell and for the set of neighboring cells; and causing data communication to the selected transmission direction in the cell during the time interval.

In some implementations, a message indicating a request for delivery of data to user equipment (UE) (e.g. an IoT device) operative for communications in a mobile network may be received from an application server. One or more first loading or congestion indication values indicative of a first loading or congestion at one or more first network nodes along a first mobile network route may be obtained. In addition, one or more second loading or congestion indication values indicative of a second loading or congestion at one or more second network nodes along a second mobile network route may be obtained. The first or the second mobile network route may be selected based on at least one of the one or more first and the second loading or congestion indication values. The data may be delivered to the UE over the selected mobile network route.

Aspects of the subject disclosure may include, for example, computing a first time gap associated with a completion of a first transfer of first data via a first network connection and a completion of a second transfer of second data via a second network connection that is different from the first network connection, determining, based on the computing of the first time gap, that the first time gap exceeds a threshold, and adjusting, based on the determining, respective shares of third data that are to be transferred via the first network connection and the second network connection. Other embodiments are disclosed.

System, device, and method of cellular congestion management without cell awareness. A system defines applications as important or non-important. The system measures and monitors parameters related to cellular traffic, and remotely generates an estimate that a first User Equipment (UE) is experiencing cellular traffic congestion. A Deep Packet Inspection (DPI) Engine determines that the first UE is utilizing a first communication flow associated with an Important Application, and is also utilizing a second communication flow associated with a Non-Important Application. Filtering pass-through bitrate limits are enforced, selectively and remotely, on communication flows of the first UE, by enforcing a reduced bitrate limit on the second communication flow that is associated with a Non-Important Application, and by not enforcing a reduced bitrate limit on the first communication flow that is associated with an Important Application.

System, device, and method of cellular congestion management without cell awareness. A system defines applications as important or non-important. The system measures and monitors parameters related to cellular traffic, and remotely generates an estimate that a first User Equipment (UE) is experiencing cellular traffic congestion. A Deep Packet Inspection (DPI) Engine determines that the first UE is utilizing a first communication flow associated with an Important Application, and is also utilizing a second communication flow associated with a Non-Important Application. Filtering pass-through bitrate limits are enforced, selectively and remotely, on communication flows of the first UE, by enforcing a reduced bitrate limit on the second communication flow that is associated with a Non-Important Application, and by not enforcing a reduced bitrate limit on the first communication flow that is associated with an Important Application.