One or more computing devices, systems, and/or methods for implementing differentiated mobility schemes are provided. In an example, a communication device may be identified as being connected with a first base station. A selection criterion may be identified based upon a characteristic associated with the communication device. A mobility scheme may be selected from a set of mobility schemes based upon the selection criterion. One or more thresholds of the mobility scheme may be communicated to the communication device.

The present disclosure relates to methods and nodes in an integrated access and backhaul (IAB) network. In one aspect, a method for a local breakout, performed in a first network node of the IAB network is provided. The first network node is being in communication with a core network, and the method comprises providing a network connection between the first network node and a local data network having a first network address, receiving a data traffic, transmitted by a user equipment (UE), wherein the data traffic is destined for a central application server having a second network address and being in communication with the core network. If the at a traffic meets a requirement for the local breakout from the first network node, the method comprises forwarding the data traffic to a local application server of the local data network and receiving from the application server of the local data network, a selected part of the data traffic destined for the central application server. The method further comprises transmitting the selected part of the data traffic to the central application server, whereby mitigating data traffic overload of the IAB network.

Apparatuses, methods, and systems are disclosed for accessing a local data network via a mobile data connection. One apparatus includes a processor that determines to configure a first data connection to provide access to a local data network in addition to the remote data network based on information received from a session management function (SMF) and activates a network interface that communicates with the local data network in response to determining to configure the first data connection to provide access to the local data network. The processor transmits a downlink data packet to the remote unit over the first data connection and provides the remote unit with access to one or more services via the local data network using the activated network interface.

A network device receives location information for a user equipment device (UE), an application identifier (ID), and a latency requirement associated with a data session involving the UE. The network device retrieves from a database, based on the UE's location information, the application ID, and the latency requirement, Multi-Access Edge Computing (MEC) selection weight values associated with multiple MEC platforms. The network device selects a MEC platform, from among the multiple MEC platforms, based on the retrieved MEC selection weight values, and causes the data session to be established between the selected MEC platform and the UE.

The present disclosure provides a backhaul link establishment method, a base station, and a device. The method includes: sending, by a base station, an offloading bearer request message to a first LPN according to a backhaul offloading establishment request message; receiving, by the base station, an offloading bearer acknowledgement message sent by the first LPN; sending, by the base station, an offloading bearer configuration message to a first UE-relay; and sending, by the base station, a received ID of a service bearer and received second S1 configuration information of the service bearer to a core network element by using an MME. In this way, backhaul load on uplink/downlink resources of the base station is reduced.

There is provided a network apparatus comprising: means for storing a mapping, the mapping comprising an indication of a first virtual network and at least one other virtual network configured to provide a service at a lower quality than the first virtual network; means for receiving, from another network apparatus, a request to provide a service using the first virtual network; and means for using the mapping and the indication of the first virtual network to select a virtual network to provide the requested service.

The disclosed technology is directed towards preventing a handover of a Wi-Fi call to a Fifth Generation (5G) standalone cellular network. In one alternative, a 5G standalone usage setting is disabled on a mobile device when Wi-Fi calling is enabled on the mobile device. In another alternative, a 5G standalone usage setting is disabled on a mobile device when Wi-Fi calling is enabled on the mobile device and the mobile device is connected to a Wi-Fi network, which facilitates camping on a 5G standalone network when the mobile device is not connected to a Wi-Fi network. In yet another alternative, a 5G standalone usage setting is disabled on a mobile device when an evolved packet data gateway (ePDG) tunnel is set up on the mobile device, which similarly facilitates camping on a 5G standalone network when the ePDG tunnel is torn down.

A method for use in a source long term evolution (LTE) mobility management entity (MME) and an MME are disclosed. The method includes receiving a relocation request from an evolved Node B (eNB), determining a handover target global system for mobile (GSM)/enhanced data rates for GSM evolution (EDGE) radio access network (GERAN) system for a handover of a wireless transmit/receive unit (WTRU) based on the received relocation request, identifying a serving General Packet Radio Service (GPRS) support node (SGSN) that controls a target GERAN cell, and forwarding the relocation request to a target SGSN.

A wireless user device uses a wireless network slice. To use the slice, the wireless user device exchanges source signaling with a source Access and Mobility Management Function (AMF). During the exchange of the source signaling, the wireless user device exchanges target signaling with target AMFs. The wireless user device determines AMF characteristics of the target AMFs based on the target signaling. The wireless user device selects one of the target AMFs based on the AMF characteristics and slice requirements of the wireless network slice. The wireless user device exchanges slice signaling with the selected one of the target AMFs, and in response, exchanges data with the wireless network slice.

Systems, methods and computer software are disclosed for providing a bubble network are described. In one embodiment, a method is disclosed including providing an isolated base station having a coverage area, providing a local HetNet Gateway (HNG) disposed within the coverage area and in communication with the isolated base station, providing a local Evolved Packet Core (EPC) in communication with the local HNG and disposed within the coverage area, and wherein the bubble network is disconnected from a mobile operator core network.