A method for wireless communication network control includes (1) receiving, at an information technology (IT) device, a first steering policy from an application manager remote from the IT device, the first steering policy specifying a first allocation of data among a plurality of wireless communication links available to the IT device; and (2) sending uplink or downlink data from a first application client on the IT device to a mobility manager remote from the IT device over at least one of the plurality of wireless communication links available to the IT device, according to the first allocation of data.

An electronic device discussed herein may include radio frequency communication circuitry for communication on a radio frequency network according to a communication configuration, a processor, and memory. The memory may store instructions that, when executed by the processor, cause the electronic device to perform operations including receiving, a first muting configuration indicating when the radio frequency communication circuitry is to communicate using a first type of communication on a first frequency band and when the radio frequency communication circuitry is to communicate using a second type of communication on a second frequency band, where the first frequency band may overlap with the second frequency band. The memory may store instructions that, when executed by the processor, cause the electronic device to perform operations including transmitting or receiving a data packet using the radio frequency communication circuitry according to the communication configuration.

A computer implemented method for controlling call capacity in a mobile network. The method includes: activating a mass event mode in a first cell of a first base station, wherein the first cell is a high frequency band cell, and wherein operating in the mass event mode comprises: checking if any low frequency band cells are available in a first sector served by the first cell; and responsive to detecting that one or more low frequency band cells are available, switching, at least some, voice call connections of the users of the first cell to at least some of the available low frequency band cells.

A system for offloading traffic from a cellular network to a broadcast network is provided. The offloading mechanism caters to both unicast and broadcast traffic. The system includes a converged cellular core network, World Wide Web, a CDN, a Broadcast Offload Packet Core (BO-PC), a cellular base station, a Broadcast Radio Head, and a converged UE. The converged cellular core network includes an enhanced packet core, a policy rules engine and a packet inspection and steering unit. The BO-PC includes a Broadcast Proxy, a subscriber database, a Broadcast Offload Service Center, a Broadcast Offload Gateway and an analytics engine. For offloading the unicast traffic, the packet inspection and steering unit identifies sessions that are offloaded for supporting offload of the traffic from the converged cellular core network to the broadcast network.

A device may perform dynamic load balancing to identify one or more service devices, of a group of service devices, that is to apply a set of network services to traffic associated with a session of a subscriber device. The device may provide outgoing traffic, associated with the session, to the one or more service devices based on identifying the one or more service devices. The outgoing traffic may be provided to cause the one or more service devices to apply the set of network services to the outgoing traffic. The device may provide, to another device, information that identifies the one or more service devices. The information that identifies the one or more service devices may be provided to cause the other device to provide incoming traffic, associated with the session, to the one or more service devices to apply the set of network services to the incoming traffic.

A disclosed method is performed at an access point including a processor and non-transitory memory. The method includes receiving a request message from a client device, where the request message includes a request for an allocation of a wireless channel for the client device from the access point. The method further includes exchanging candidate and load information with a plurality of other access points. The method additionally includes selecting a preferred access point from the access point and the plurality of other access points based on the candidate and load information exchanged with the plurality of other access points. The method also includes facilitating the allocation of the wireless channel for the client device from the preferred access point.

Methods, a policy server (110) and a traffic steering server (120) for managing traffic steering policies for steering of traffic of a user equipment are disclosed. The policy server (110) generates (A020) a policy request, where-in the policy request comprises the traffic steering policies, wherein the traffic steering policies include a first traffic steering policy and a second traffic steering policy, both the first and second traffic steering policies being applicable to the traffic in one direction with respect to the user equipment. The policy server (110) sends (A030) the policy request to the traffic steering server (120). The traffic steering server (120) applies (A070) at least one of the first and second traffic steering policies to manage the traffic. Corresponding computer programs and computer program carriers are also disclosed.

A programmable device includes a plurality of first partial reconfiguration slots, a plurality of transceivers and a second partial reconfiguration slot. The plurality of first partial reconfiguration slots are configured to execute one or more applications or network functions. The second partial reconfiguration slot is configured to route data traffic flows between the plurality of first partial reconfiguration slots and the plurality of transceivers.

An apparatus for acquisition of fast multi-channel data based on a long range wide area network (LoRaWAN) includes: a contention period data processor configured to insert a flag indicating the apparatus itself into an initial contention resolution queue (CRQ), determine whether a flag is a flag of the apparatus, and transmit an access request sequence (ARS) during a contention period; a feedback period data processor configured to check whether information taken out from a data transmission queue (DTQ) is a flag of the apparats, check whether a contention of the apparatus is resolved, and check whether there is a slot for which contention is not resolved among other slots during a feedback period.

An apparatus for acquisition of fast multi-channel data based on a long range wide area network (LoRaWAN) includes: a contention period data processor configured to insert a flag indicating the apparatus itself into an initial contention resolution queue (CRQ), determine whether a flag is a flag of the apparatus, and transmit an access request sequence (ARS) during a contention period; a feedback period data processor configured to check whether information taken out from a data transmission queue (DTQ) is a flag of the apparats, check whether a contention of the apparatus is resolved, and check whether there is a slot for which contention is not resolved among other slots during a feedback period.