An example embodiment may involve receiving, by a first mobile application executing on a mobile device, a selection of a uniform resource locator (URL) related to an application server device; transmitting, by the first mobile application, a first request to the application server device, wherein the first request is directed to the application server device by way a virtual private network (VPN) or proxy session between the mobile device and a VPN server device or proxy server device, and wherein the first request contains the URL; receiving, by the mobile device, a push notification from a scanning server device associated with the VPN server device or proxy server device, wherein the push notification contains the URL or a different URL; providing, by the mobile device, the URL from the push notification to a second mobile application executing on the mobile device; and transmitting, by the second mobile application, a second request to the application server device, wherein the second request contains the URL from the push notification.

A wireless communication network exchanges data communication over Session Communication Proxies (SCPs). In the wireless network, the SCPs determine and transfer location information and status data to a Network Repository Function (NRF). The NRF receives the location information and status data and prioritizes the SCPs based on the location information and the status data. A requesting Network Function (NF) transfers an NF request to the NRF. The NRF receives the NF request from the requesting NF. In response, the NRF generates and transfers a list that prioritizes the SCPs based on the location information and the status data to the requesting NF. The requesting NF selects one of the SCPs based on the location information and the status data and transfers NF data to the selected one of the SCPs. The selected one of the SCPs forwards the NF data to a target NF.

Methods, systems, and devices for wireless communications are described. A first and second user equipment (UE) may perform a handshake procedure to establish a cooperation agreement designating one or more frequency and time resources which the first UE is to act as the proxy device for the second UE. For example, the first UE may receive a sidelink message directed to a second UE from a third UE. The first UE may determine to act as a proxy device for the second UE with respect to the sidelink message based on the sidelink message being received during a time resource designated for the first UE to act as the proxy device for the second UE. The first UE may proceed to transmit to the third UE feedback information associated with the sidelink message, and may transmit the sidelink message to the second UE on behalf of the third UE.

Aspects of the subject disclosure may include, for example, receiving network-related information associated with a first RAN that includes a first RIC, obtaining, from an artificial intelligence (AI) model synchronization system associated with a second RAN, data relating to an AI model deployed by a second RIC of the second RAN, determining, based on the data relating to the AI model and the network-related information associated with the first RAN, that the AI model can be leveraged by the first RAN to improve network performance of the first RAN, performing synchronization with the AI model synchronization system to obtain the AI model, responsive to the determining that the AI model can be leveraged by the first RAN to improve the network performance of the first RAN, and causing the first RIC to deploy the AI model in the first RAN after the performing the synchronization. Other embodiments are disclosed.

Systems and methods of scheduling data in background services on mobile devices are disclosed. An example method includes identifying data consumption patterns on a mobile device. The method also includes determining sensitivity of data arriving at the mobile device based on the data consumption patterns. The method also includes aggregating network access by background services on the mobile device according to a schedule based on the sensitivity of the data arriving at the mobile device.

A user device registers with a proxy-call session control function device (P-CSCF) associated with an Internet protocol (IP) multimedia subsystem (IMS). The user device forwards a request to the P-CSCF requesting a session via the IMS for an IMS call. If a response to the request is not received from the P-CSCF during a time period after forwarding the request, the user device attempts to newly register with the P-CSCF. If the new registration is successful, the user device re-forwards the request to the P-CSCF. Otherwise, if the new registration with the P-CSCF is unsuccessful, the user device registers with a different P-CSCF and forwards the request to the second P-CSCF.

Techniques described herein include utilizing a mobile device as a proxy receiver for a vehicle in a V2X environment. In some embodiments, the mobile device may be configured to obtain vehicle and/or occupant metadata and store such data in memory at the mobile device. At a subsequent time, the mobile device may receive a V2X data message from a remote device (e.g., a V2X capable vehicle, another proxy device, a roadside unit, or any suitable device of the V2X environment that is different from the mobile device). The mobile device may process the data message based at least in part on the vehicle metadata and/or occupant metadata and perform one or more operations in response to processing the data message.

The present disclosure provides a method for forwarding to a Transport Control Protocol (TCP) receiver a TCP transmission sent from a TCP sender. The method includes: determining Time Division Duplex (TDD) reconfiguration time required for a TDD reconfiguration; comparing the TDD reconfiguration time with a predetermined threshold; suspending the forwarding of the TCP transmission to the TCP receiver during the TDD reconfiguration time if the TDD reconfiguration time is larger than the predetermined threshold; and resuming the suspended forwarding of the TCP transmission after the TDD reconfiguration time has lapsed. The present disclosure also provides a method for transmitting a TCP transmission to a TCP receiver, a base station and a user equipment.

An electronic device may include a communication circuit; and a processor operatively connected to the communication circuit, wherein the processor may be configured to perform synchronization with neighbor awareness networking (NAN) based on NAN cluster information included in a signal broadcast by an external electronic device included in the NAN, to determine whether to switch to a second communication mode operable with lower power than that of the first communication mode based on a state of the electronic device while operating in the first communication mode capable of transmitting and/or receiving data each interval having a first value, to search for an external electronic device capable of performing a function of a proxy server among external electronic devices included in the NAN corresponding to determining to switch to the second communication mode, to transmit a proxy registration request signal to the found external electronic device, and to operate in the second communication mode corresponding to completion of registration to the external electronic device, wherein the proxy registration request signal may include information related to a function to be performed by the external electronic device instead of the electronic device while operating in the second communication mode. In addition, various embodiments are possible.

Disclosed are a method and an apparatus for reducing current consumption between proximity electronic devices in a NAN based low-power near field communication network. An electronic device may include a processor configured to: broadcast a first signal notifying that the electronic device can operate as a first proxy server, receive a first proxy client registration request from a first external electronic device, transmit a first proxy client registration response, receive a fourth signal notifying that a second external electronic device can operate as a second proxy server, transmit a second proxy client registration request to the second external electronic device, receive a second proxy client registration response from the second external electronic device, and operate the electronic device as a first proxy client of the second external electronic device in parallel with operating the electronic device as the first proxy server of the first external electronic device.