Aspects of the disclosure relate to a user equipment (UE) configured to schedule resource management procedures including measurements and tracking loop procedures. In some examples, the UE includes at least one antenna pair and two or more receivers. The UE may be configured to determine a plurality of combinations of antenna pairs and component carriers, where each component carrier is associated with a particular frequency. The UE may further be configured to schedule measurements/tracking loop procedures to available receivers first and utilize a selection algorithm to select combinations of antenna pairs and component carriers and map the selected combinations to the remaining of the available receivers to perform tracking loop procedures. Other aspects, features, and embodiments are also claimed and described.

A computer method and system for analyzing performance of a 5G communication network for determining 4G traffic offload characteristics. Determine relative spectrum efficiency for data downlinks and uplinks in the 5G communication network and determine values for pairs of 4G LTE primary cells and 5G NR primary cells. A heatmap is generated utilizing the determined values for depicting 4G traffic offload characteristics in a 5G communication network wherein the generated heatmap includes a generated line depicting a connection between a LTE PCell to a 5G NR PScell wherein a width of the generated line is scalable relative to a determined percentage of 5G utilized traffic in the 5G communication system.

Aspects of the subject disclosure may include, for example, a process or apparatus for receiving, by a processing system including a processor, cell traffic reports for cells of a radio communication network, performing a reconfiguration analysis to identify reconfiguration information to reconfigure the radio communication network according to changing network conditions, and communicating the reconfiguration information defining a new cell configuration for the cells of the radio communication network and communicating information defining a new reconfiguration time for the cells to substantially synchronously switch to communicating according to the reconfiguration information. The receiving the cell traffic reports, the performing the reconfiguration analysis and the communicating the reconfiguration information occur in substantially real time. Other embodiments are disclosed.

Systems and methods are provided for in-vehicle data-driven connectivity optimization in a network of moving things. An on-board unit configured for deployment in a vehicle may obtain, during operations in an area of the network of moving things, connectivity-related data relating to coverage within the area, and generate or update, based on processing of the obtained connectivity-related data, a networking decision model. The networking decision model is configured for optimizing connectivity to the one or more access points in or associated with the network of moving things. The networking decision model may be shared with other on-board units deployed in other vehicles and/or with a Cloud-based network node in the network.

The disclosure relates to a network function for supporting end-to-end communication services in a communication network, wherein the communication network comprises a first management system for managing a 3GPP 5G subnetwork and a second management system for managing a 3GPP legacy subnetwork and/or a non-3GPP subnetwork. The network function provides an interface between the first management system and the second management system. The first management system and/or the second management system comprises a plurality of network management functions and/or network management function instances. The network function also selects one or more of the plurality of network management functions and or network management function instances in response to a service request on the basis of a load balancing requirement, a minimum latency requirement defined by the service request and/or a quality of a service requirement defined by the service request.

Relay service is enabled between a residential gateway and a remote user. For example, a 5G residential gateway (5G-RG) may include a relay user equipment (UE) to enable relay service for a 5G core (5GC)-capable UE behind the 5G-RG to connect to the 5GC. The relay UE of the 5G-RG may provide a trusted/untrusted non-3GPP access network for L2 or L3 transport connection to the 5GC-capable UE.

In one embodiment, a method comprises obtaining, by a first network element comprising processing logic, notification of a plurality of events associated with a plurality of communication sessions, wherein the events include at least one of a mid-session event or an end-session event, wherein the plurality of events are communicated to a routing agent using a first communication protocol by a plurality of second network elements; receiving, by the first network element, a request via a second communication protocol for a first communication session to be established for a client computing device; selecting, by the first network element, one or more network elements from the second network elements for the communication session based on the at least one of a mid-session or an end-session event; and communicating, by the first network element, identification information of the one or more network elements selected for use in the first communication session.

A wireless local area network, WLAN, node (400) is adapted to be comprised in an integrated wireless communications network comprising a WLAN and a cellular communications network. The WLAN node (400) comprises a receiving module (401) adapted to receive traffic data from a wireless device. A differentiation module (403) is adapted to determine whether the received traffic data relates to a first traffic type which is to be routed locally within the WLAN or a second traffic type which is to be routed to the cellular communication network. A processing module (405) is adapted to control the handling of the traffic data according to whether the traffic data is determined as relating to the first traffic type or the second traffic type.

Systems and methods are provided for in-vehicle data-driven connectivity optimization in a network of moving things. An on-board unit configured for deployment in a vehicle may obtain, during operations in an area of the network of moving things, connectivity-related data relating to coverage within the area, and generate or update, based on processing of the obtained connectivity-related data, a networking decision model. The networking decision model is configured for optimizing connectivity to the one or more access points in or associated with the network of moving things. The networking decision model may be shared with other on-board units deployed in other vehicles and/or with a Cloud-based network node in the network.

Methods and systems for providing an enhanced proximity services. The method includes monitoring, by a proximity controller provisioned in a preferred network, dual subscriber identification module (SIM) dual subscriber (DSDS) devices operating in the preferred network, detecting, by the proximity controller, a DSDS device operating in a non-preferred network, wherein the DSDS devices and the DSDS device are configured to switchably operate in one of the preferred network or the non-preferred network based on coverage, locating, by the proximity controller, from the monitored DSDS devices a DSDS device proximate to the DSDS device operating in the non-preferred network, and enabling, by the proximity controller, the proximate DSDS device and the DSDS device operating in the non-preferred network to establish a sidelink communication channel between the proximate DSDS device and the DSDS device operating in the non-preferred network for offloading data communications from the non-preferred network to the preferred network.