A location verification system according to an embodiment of the present disclosure includes a plurality of base stations located in respective preset areas and transmitting, to an adjacent mobile communication device, location verification information obtained by signing GPS information on the base stations with a private key. It is possible to expect an effect of re-verifying a location of a mobile communication device, such as a drone or a smart car, at a destination, when the mobile communication device has moved to the destination based on GPS information.

A system includes a user equipment (UE) traveling at least at a predetermined velocity. The UE is in RRC_INACTIVE state since time T. The system further includes at least a first base station and a second base station. The first base station receives an RRC_INACTIVE state message from the UE. The RRC_INACTIVE state message includes a location and a velocity of the UE, and a time-lapse, which is an elapsed duration since T. In response to a paging message from a core network, the first base station predicts a location of the UE. In response to the UE being within range of the first base station, the first base station sends the paging message to the UE. In response to the UE being within range of the second base station, the first base station sends a request to the second base station to send the paging message to the UE.

A method is performed at a server that manages embedded subscriber identity module (eSIM) profiles. The method includes, when a user equipment that belongs to a global enterprise network relocates from a first locale to a second locale in which a first private network and a second private network of the global enterprise network are located, wherein the user equipment includes a locale-specific first eSIM profile that includes a first non-public network identifier of the first private network, receiving, from the user equipment over a network in the second locale, information that indicates the user equipment is in the second locale. The method further includes identifying the second private network based on the information, and generating a locale-specific second eSIM profile that includes a second non-public network identifier for the second private network. The method includes configuring the user equipment with the locale-specific second eSIM profile.

A system configured to determine wireless carrier compatibility information for a wireless device feature for at least one wireless network and a wireless device. The wireless device includes a wireless device processor configured to obtain a wireless device configuration; the wireless device processor further configured to obtain a wireless network configuration; the wireless device processor further configured to analyze the wireless device configuration and the wireless network configuration and determine wireless carrier compatibility information for a wireless device feature; and a display configured to receive the wireless carrier compatibility information and display the wireless carrier compatibility information in response to the wireless device processor for the wireless device feature.

In selected embodiments, on-premises equipment of a cellular network provides local breakout functionality so that user plane data packets (PDNs/PDUs) are routed between the home/enterprise network and the Internet directly, bypassing a cloud-based core of the cellular network. The UE's control traffic is still routed to/from the core. The core may be an Evolved Packet Core (EPC) in a 4G LTE network, or a 5G Core (5GC) in a 5G network. The UE's IP addresses may be assigned by the core, or locally, by the on-premises equipment. Providing the IP context from the on-premises network allows the UE to connect to local devices, e.g., printers, disc raids, gaming and streaming nodes, and other local devices. The local IP context also pushes the complexity of the EPC core deployment to the cloud while reducing the overhead of cloud processing that comes with user plane data processing.

In selected embodiments, on-premises equipment of a cellular network provides local breakout functionality so that user plane data packets (PDNs/PDUs) are routed between the home/enterprise network and the Internet directly, bypassing a cloud-based core of the cellular network. The UE's control traffic is still routed to/from the core. The core may be an Evolved Packet Core (EPC) in a 4G LTE network, or a 5G Core (5GC) in a 5G network. The UE's IP addresses may be assigned by the core, or locally, by the on-premises equipment. Providing the IP context from the on-premises network allows the UE to connect to local devices, e.g., printers, disc raids, gaming and streaming nodes, and other local devices. The local IP context also pushes the complexity of the EPC core deployment to the cloud while reducing the overhead of cloud processing that comes with user plane data processing.

Certain aspects of the present disclosure provide techniques for over-the-air synchronization of integrated access and backhaul communications. An example method that may be performed by a network entity includes receiving, from a first wireless node, an indication of a value of a timing adjustment factor associated with a communication between the first wireless node and a second wireless node and communicating with the first wireless node or the second wireless node based on the value of the timing adjustment factor.

Certain aspects of the present disclosure provide techniques for over-the-air synchronization of integrated access and backhaul communications. An example method that may be performed by a network entity includes receiving, from a first wireless node, an indication of a value of a timing adjustment factor associated with a communication between the first wireless node and a second wireless node and communicating with the first wireless node or the second wireless node based on the value of the timing adjustment factor.

Provided is a method for performing relay forwarding on integrated access and backhaul (IAB) links. The method includes receiving, by a first IAB node, a data packet; and transmitting, by the first IAB node, the data packet to an IAB donor. Further provided are an information acquisition method, an IAB node, an IAB donor node and a storage medium.

Provided is a method for performing relay forwarding on integrated access and backhaul (IAB) links. The method includes receiving, by a first IAB node, a data packet; and transmitting, by the first IAB node, the data packet to an IAB donor. Further provided are an information acquisition method, an IAB node, an IAB donor node and a storage medium.