Abstract: A base station of a radio access network (RAN) can be configured to prioritize standalone (SA) 5G traffic over non-standalone (NSA) 5G traffic in certain situations, to improve user experiences associated with 5G-specific services implemented via SA 5G networks. The base station can generally instruct 5G user equipment (UE), such SA UEs and NSA UEs, to prioritize camping on an SA priority band. However, if a RAN load level is at or above a threshold, the base station can instruct NSA UEs to prioritize camping on a different priority band in order to relieve congestion on the SA priority band and/or preserve remaining capacity on the SA priority band for SA UEs. When the RAN load level is above a threshold, the base station can also, or alternately, at least briefly delay traffic associated with NSA UEs to prioritize transmission of traffic associated with SA UEs.

Abstract: A wireless UE wirelessly attaches to a network controller over a source RAN. The UE transfers UE capabilities that comprise a Public Land Mobile Network Identifier (PLMN ID) and transfers a slice request for a network slice type to the network controller over the source RAN. The network controller selects a network slice based on the requested network slice type. The network controller selects a mobility profile that comprises handover criteria based on the requested slice type and the PLMN ID. The UE exchanges user data with a user plane over the selected network slice. The UE determines a handover requirement based on the handover criteria and identifies a set of target RANs. The UE selects one of the target RANs based on the handover criteria and hands over to the target RAN. The UE exchanges additional user data with user plane over the network slice and the target RAN.

Abstract: Methods, media, and systems are provided for restricting an uplink Multiple Input Multiple Output (MIMO) assignment based on fading, battery data, or location data associated with a user device in an mmWave system. Fading data, location data, or battery data is received from one or more user devices. Based on the received data, a determination is made using the data received (e.g., determining the battery data of the user device is below a threshold or determining the location of the user device). In response, the assignment of the user device to an uplink MIMO layer of available MIMO layers is restricted. The restricted uplink MIMO layer is a higher MIMO layer than another MIMO layer of the available MIMO layers. In response to restricting the assignment, the user device may be assigned to an available MIMO layer that is a lower MIMO layer than the restricted MIMO layer.

Abstract: A wireless User Equipment (UE) controls a wireless network slice type that has slice requirements. In the UE, source Radio Resource Control (RRC) circuitry exchanges source signaling with a source Access and Mobility Management Function (AMF). During the exchange of the source signaling, target RRC circuitry exchanges target signaling with target AMFs and determines AMF characteristics. The target RRC circuitry compares the AMF characteristics to the slice requirements and selects one of the target AMFs based on the comparison. The source or target RRC circuitry exchange additional target signaling with the selected one of the target AMFs to use the wireless network slice type. User-plane circuitry exchanges user data with the wireless network slice which is controlled by the selected target AMF.

Abstract: A wireless communication network serves a wireless User Equipment (UE) over a backhaul link. A wireless network core identifies a wireless access node and a radio band for the wireless UE. The wireless network core selects a backhaul data rate for the wireless UE based on the radio band for the wireless UE. The wireless network core exchanges user data with the wireless access node over the backhaul link using the selected backhaul data rate. The wireless access node exchanges the user data with the wireless network core over the backhaul link using the selected backhaul data rate. The wireless access node wirelessly exchanges the user data with the wireless UE over the radio band.

Abstract: Methods, media, and systems are provided for restricting an uplink Multiple Input Multiple Output (MIMO) assignment based on fading, battery data, or location data associated with a user device in an mmWave system. Fading data, location data, or battery data is received from one or more user devices. Based on the received data, a determination is made using the data received (e.g., determining the battery data of the user device is below a threshold or determining the location of the user device). In response, the assignment of the user device to an uplink MIMO layer of available MIMO layers is restricted. The restricted uplink MIMO layer is a higher MIMO layer than another MIMO layer of the available MIMO layers. In response to restricting the assignment, the user device may be assigned to an available MIMO layer that is a lower MIMO layer than the restricted MIMO layer.

Abstract: A wireless User Equipment (UE) controls a wireless network slice type that has slice requirements. In the UE, source Radio Resource Control (RRC) circuitry exchanges source signaling with a source Access and Mobility Management Function (AMF). During the exchange of the source signaling, target RRC circuitry exchanges target signaling with target AMFs and determines AMF characteristics. The target RRC circuitry compares the AMF characteristics to the slice requirements and selects one of the target AMFs based on the comparison. The source or target RRC circuitry exchange additional target signaling with the selected one of the target AMFs to use the wireless network slice type. User-plane circuitry exchanges user data with the wireless network slice which is controlled by the selected target AMF.

Abstract: In a wireless communication network, a wireless network core and wireless access nodes exchange user data using data rates. The wireless access nodes wirelessly exchange the data with the wireless UE over radio bands. The wireless network core determines a data rate level for the wireless UE based on the data rates. Subsequently, the wireless network core identifies a serving wireless access node and a serving radio band. The wireless network core determines a new data rate based on the data rate level and the serving radio band. The wireless network core and the serving wireless access node exchange new data using the new data rate. The serving wireless access node wirelessly exchanges the new data with the wireless UE over the serving radio band.

Abstract: A primary wireless access node receives signaling that indicates primary power headroom for a User Equipment (UE) when transmitting to the primary wireless access node and secondary power headroom for the UE when transmitting to a secondary wireless access node. The primary wireless access node determines a primary uplink grant and a secondary uplink grant for the UE and transfers the secondary uplink grant amount to the secondary wireless access node. The primary wireless access node wirelessly transfers the primary uplink grant to the UE and wirelessly receives primary user data from the UE based on the primary uplink grant. The secondary wireless access node receives the secondary uplink grant from the primary wireless access node. The secondary wireless access node wirelessly transfers the secondary uplink grant to the UE and wirelessly receives secondary user data from the UE based on the secondary uplink grant.

Abstract: A wireless User Equipment (UE) to optimize network communications for a user application. A UE operating system receives a user permission for the user application to access network characteristics. The user application calls the operating system for the network characteristics, and the operating system obtains the network characteristics from wireless network circuitry in response to the user permission. The operating system transfers the network characteristics to the user application. The user application selects one of multiple wireless communication networks based on the network characteristics. The wireless network circuitry wirelessly exchanges user data for the user application with the selected wireless communication network.

Abstract: A wireless User Equipment (UE) uses different handover types for different user applications that are served by different wireless network slices. The wireless UE executes a selected one of the user applications and selects one of the wireless network slices to serve the selected one of the user applications. The wireless UE selects one of the handover types for the selected one of the wireless network slices. The wireless UE wirelessly exchanges application data for the selected one of the user applications with a wireless communication network. The wireless UE and the wireless communication network use the selected one of the handover types for the wireless exchange of the application data. The selected one of the wireless network slices processes the application data in the wireless communication network for the selected one of the user applications.

Abstract: A method and system for dynamically controlling connectivity of a user equipment device (UE) when the UE has standalone connectivity with a first access node under a first radio access technology (RAT). An example method includes the UE detecting that the UE is within threshold strong coverage of a second access node under a second RAT, and the UE making a selection between (i) responsively handing over from the first access node to the second access node and (ii) having dual-connectivity with the first access node and the second access node. Further, the example method includes the UE informing the first access node of the UE's selection, perhaps together with an inter-RAT measurement report reporting that the UE is within threshold strong coverage of the second access node, and the first access node responsively taking action in accordance with the UE's selection.

Abstract: A wireless User Equipment (UE) executes a user application and wirelessly exchanges signaling with a wireless communication network over a source frequency band. The UE selects a wireless network slice responsive to the signaling. The UE selects a target frequency band and a handover type based on a characteristic of the wireless network slice. The UE requests the target frequency band and the handover type by wirelessly exchanging signaling with the wireless communication network over the source frequency band. The UE wirelessly exchanges data for the user application with the wireless communication network over the target frequency band. The wireless network slice handles the data to deliver the wireless data service to the wireless UE for the user application. The UE and the wireless communication network use the handover type to handover the wireless UE during the delivery of the wireless data service.

Abstract: A mobile communication device that customizes a user interface of the mobile communication device based on a pre-loaded customization manifest.

Abstract: A wireless User Equipment (UE) executes a user application and wirelessly exchanges signaling with a wireless communication network over a source frequency band. The UE selects a wireless network slice responsive to the signaling. The UE selects a target frequency band and a handover type based on a characteristic of the wireless network slice. The UE requests the target frequency band and the handover type by wirelessly exchanging signaling with the wireless communication network over the source frequency band. The UE wirelessly exchanges data for the user application with the wireless communication network over the target frequency band. The wireless network slice handles the data to deliver the wireless data service to the wireless UE for the user application. The UE and the wireless communication network use the handover type to handover the wireless UE during the delivery of the wireless data service.

Abstract: Methods and systems are provided for restricting an uplink Multiple Input Multiple Output (MIMO) assignment based on fading in an mmWave system. The methods and systems receive fading data from one or more user devices. Based on the received fading data, the methods and systems determine that a threshold number of the one or more user devices satisfies a threshold level of fading. In response to the threshold number satisfying the threshold level of fading, the methods and systems dynamically restrict the uplink MIMO assignment for at least one user device satisfying the threshold level of fading. In response to dynamically restricting the uplink MIMO assignment, the methods and systems assign the at least one user device to a lower MIMO layer of available MIMO layers.

Abstract: When a first radio of a UE has an air-interface connection with an access node on a first carrier and the UE encounters a trigger for the UE to scan for and report to the access node coverage on a second carrier, a second radio of the UE, rather than the first radio of the UE, will conduct the scanning, and the first radio of the UE will then report to access node over the air-interface connection on the first carrier a result of the scanning conducted by the second radio. Optimally, the first radio of the UE thus need not tune away from its air-interface connection with the access node in order for the UE to scan for target coverage on the second carrier. And the process could thereby help avoid the interruption of communication between the UE and the access node on the air-interface connection over the first carrier.

Abstract: A wireless access node wirelessly broadcasts System Information Blocks (SIBs) that indicate individual slice characteristics for wireless network slices. A wireless UE wirelessly receives the SIBs, selects one of the slices based on user requirements for a user application and the individual slice characteristics for the slices, and transfers UE capability information that indicates the selected slice to the wireless access node. The wireless access node transfers the UE capability information to an Access and Mobility Management Function (AMF). The AMF authorizes the wireless UE for the selected slice and selects Quality-of-Service (QoS) parameters for the wireless UE that correspond to the individual slice characteristics for the selected slice. The AMF transfers signaling to the wireless access node to serve the wireless UE per the selected QoS parameters. The wireless access node wirelessly exchanges user data with the wireless UE per the selected QoS parameters.

Abstract: A primary wireless access node receives primary power headroom for User Equipment (UE). A secondary wireless access receives secondary power headroom for the UE and transfers the secondary power headroom to the primary wireless access node. The primary wireless access node compares the power primary headroom to the secondary power headroom to determine a primary uplink grant amount and a secondary uplink grant amount for the UE. The primary wireless access node grants primary uplink resources to the UE based on the primary uplink grant amount. The secondary wireless access node grants secondary uplink resources to the UE based on the secondary uplink grant amount. The wireless access nodes receive user data from the UE based on the uplink grant amounts.

Abstract: Dynamic reconfiguring of dual-connectivity service of a UE includes detecting that quality of the UE's second air-interface connection with a second access node is threshold poor and responsively reconfiguring the dual-connectivity service from (i) a first mode in which user plane communication of the dual-connectivity service is downlink on both the first and second air-interface connections and is uplink on the second air-interface connection but not on the first air-interface connection to (ii) a second mode in which the user-plane communication of the dual-connectivity service is downlink on both the first and second air-interface connections and is uplink on the first air-interface connection but not on the second air-interface connection.