Some demonstrative embodiments include devices, systems and/or methods to establish a connection to the Internet via a local gateway (L-GW) function for a LIPA or a SIPTO@LN. The establishment of the connection to the Internet may be performed, for example, by at least one of an E-RAB SETUP procedure, an INITIAL CONTEXT SETUP procedure, an INITIAL UE MESSAGE procedure or an UPLINK NAS TRANSPORT procedure.

Some demonstrative embodiments include devices, systems and/or methods to establish a connection to the Internet via a local gateway (L-GW) function for a LIPA or a SIPTO@LN. The establishment of the connection to the Internet may be performed, for example, by at least one of an E-RAB SETUP procedure, an INITIAL CONTEXT SETUP procedure, an INITIAL UE MESSAGE procedure or an UPLINK NAS TRANSPORT procedure.

The invention relates to a method for requesting uplink resources by a user equipment in a communication system, wherein a DRX, Discontinued Reception, function is running at the user equipment. The transmission of a scheduling request for requesting uplink resources to a radio base station is triggered upon triggering of a buffer status report in the user equipment. However, the triggering of the scheduling request is delayed such that the scheduling request is triggered in one of the subframes—preferably the first subframe—of an On-Duration period of a DRX cycle according to the DRX function. Correspondingly, the triggered scheduling request is transmitted to the radio base station in the next possible scheduling request transmission occasion after the triggering of the scheduling request is delayed.

Disclosed are various embodiments for provisioning radio-based networks on demand. In one embodiment, a request to provision a radio-based network to cover an area is received. At least one radio access network operated by at least one communication service provider that covers the area is determined. A capacity is provisioned in the radio access network(s) for the radio-based network to cover the area. At least a portion of a core network is provisioned for the radio-based network in a cloud provider network.

Disclosed are various embodiments for on-demand application-driven network slicing. In one embodiment, it is determined that an application implemented in a particular computing device has an increased quality-of-service requirement in order to send or receive data via a communications network. The increased quality-of-service requirement is greater than an existing quality-of-service provided to the application by the communications network. The application sends a request that causes capacity in a network slice having the increased quality-of-service requirement in the communications network to be allocated for the application. The data is transmitted to or from the application using the network slice.

User equipments (UEs) may be scheduled by determining relative priorities of data radio bearers (DRBs), each DRB associated with a respective UE. A limit is established dividing radio resources available for allocation in the cell during a scheduling period into at least a first limited portion and a second remaining portion. According to the determined relative priorities: a) up to the first limited portion of the radio resources are allocated to only the DRBs that have a guaranteed bit rate (GBR), and thereafter b) the second remaining portion of the radio resources are allocated to only the DRBs which have not been fully allocated from the first limited portion. Schedules indicating this allocation are transmitted to the respective UEs. In carrier aggregation where each carrier aggregated cells has a respective plurality of DRBs, relative priorities for each respective plurality of DRBs are determined for each carrier aggregated cell.

A user equipment transmits user equipment information, associated with a communication of the user equipment, to permit a base station to select a first bandwidth part, a second bandwidth part, or a third bandwidth part. The user equipment is configured to communicate by the first bandwidth part, the second bandwidth part, and the third bandwidth part. The user equipment receives, from the base station, an instruction to monitor the first bandwidth part, the second bandwidth part, or the third bandwidth part. The instruction is selected based on the user equipment information. The user equipment monitors, based on the instruction, the first bandwidth part, the second bandwidth part, or the third bandwidth part.

An application, executed by a User Equipment (“UE”), may receive an identifier, which may be used to monitor Key Performance Indicators (“KPIs”) associated with the UE. Such KPIs may be monitored in conjunction with execution of the application, such as at times that the application sends and/or receives traffic. The KPIs may be associated with sensor data, resources, and/or other features or functionality of the UE. The UE may obtain an identifier associated with the application and/or the UE from a KPI monitoring system of some embodiments, may obtain user consent to monitor and/or report KPIs associated with the application, and may provide such KPIs to the KPI monitoring system in conjunction with the identifier. The KPI monitoring system may generate aggregated KPI information, associated with the application, based on the KPIs received from the UE and/or KPIs received from one or more other sources.

A wireless sensing system includes a gateway node configured to wirelessly communicate with a plurality wireless nodes in an environment, and a first set of the plurality of wireless nodes, each wireless node of the first set configured to wirelessly communicate with the gateway node and to wirelessly communicate with other wireless nodes of the plurality of wireless nodes, each wireless node of the first set comprising a same first group identifier. The gateway node is configured to address the first set of the plurality of the wireless nodes by addressing all wireless nodes in the environment that broadcast the first group identifier.

A network device receives, from a policy control function (PCF), at least one set of multiple user equipment device (UE)-location based conditional policy rules. The network device selects a first one of the multiple UE-location based conditional policy rules based on a first geographic location of a first UE, and controls data traffic associated with the first UE using the selected first one of the plurality of UE-location based conditional policy rules.