Methods and apparatuses are described herein for dynamic PC5 communication adaptation. For example, a UE may receive, from a vehicle-to-everything control function (V2X CF) or a vehicle-to-everything application server (V2X AS), a V2X provisioning message that includes a first transmission profile and determine, based on the first transmission profile, a first range to configure PC5 communication of a plurality of UEs associated with the V2X platoon. When a number of UEs joining the V2X platoon exceeds a certain threshold, the UE may transmit, to the V2X CF or the V2X AS, a modification request message requesting a second transmission profile. The UE may receive, from the V2X CF or the V2X AS, a modification response message that includes the second transmission profile and determine, based on the second transmission profile, a second range to reconfigure the PC5 communication of the plurality of UEs associated with the V2X platoon.

Methods and apparatuses are described herein for dynamic PC5 communication adaptation. For example, a UE may receive, from a vehicle-to-everything control function (V2X CF) or a vehicle-to-everything application server (V2X AS), a V2X provisioning message that includes a first transmission profile and determine, based on the first transmission profile, a first range to configure PC5 communication of a plurality of UEs associated with the V2X platoon. When a number of UEs joining the V2X platoon exceeds a certain threshold, the UE may transmit, to the V2X CF or the V2X AS, a modification request message requesting a second transmission profile. The UE may receive, from the V2X CF or the V2X AS, a modification response message that includes the second transmission profile and determine, based on the second transmission profile, a second range to reconfigure the PC5 communication of the plurality of UEs associated with the V2X platoon.

There is provided mechanisms for enabling discovery of a service-providing NF in a 3GPP communication network. A method is performed by a Network Repository Function. The method comprises registering locality information of service-providing NFs according to locality attribute of each service-providing NF. Each locality attribute comprises structured values of location information of its service-providing NF. The method comprises obtaining a request from a service-requesting NF for one of the service-providing NFs. The request specifies a preferred locality of the requested service-providing NF. The preferred locality indicates, in terms of structured values of location information, geographical location where the service-requesting NF is deployed. The method comprises identifying, out of the service-providing NFs, that service-providing NF which has a locality attribute that best matches the preferred locality, whereby the service-providing NF closest to the geographical location where the service-requesting NF is deployed is identified. The method comprises providing a response to the service-requesting NF. The response comprises the locality attribute of the identified service-providing NF, thereby enabling discovery of the service-providing NF.

A plurality of smart city devices are configured using an application running on a mobile device. The method includes installing a particular smart city device and automatically identifying a geo-location of the particular smart city device by identifying a current geo-location of the mobile device using a location service of the mobile device. Configuration information for the particular smart city device is entered using a user interface of the mobile device. The geo-location and the configuration information of the particular smart city device are saved in the mobile device. The installing, entering, recognizing and storing steps are repeated for each of a number of the plurality of smart city devices. The saved geo-location and the configuration information for each of the number of smart city devices are uploaded from the mobile device to a remote server.

Some embodiments are directed to a session manager, a cloud service system, and a mobile device. The session manager may be configured for managing an edge computing resource in a mobile network, wherein the mobile network comprises edge nodes which are configurable to provide edge computing resources to mobile devices. The session manager may generate a session identifier for the mobile device and associate the session identifier with the mobile device. Later, the session manager may receive a request from the cloud service system for deployment of an edge computing resource for the mobile device on an edge node.

Some embodiments are directed to a session manager, a cloud service system, and a mobile device. The session manager may be configured for managing an edge computing resource in a mobile network, wherein the mobile network comprises edge nodes which are configurable to provide edge computing resources to mobile devices. The session manager may generate a session identifier for the mobile device and associate the session identifier with the mobile device. Later, the session manager may receive a request from the cloud service system for deployment of an edge computing resource for the mobile device on an edge node.

This application discloses a method for dynamically triggering instantiation of an edge application server, and an apparatus. The method includes: A first device receives first information, where the first information is for requesting information about an edge application server of a first application, or is for requesting information about a first edge enabler server, where the first edge enabler server is configured to provide information about an edge application server of a first application; and the first device requests, based on the first information, an edge application server management function entity to instantiate the edge application server of the first application. In embodiments of this application, the edge application server is instantiated based on a user requirement, so that dynamic scheduling and flexible use of a resource are improved, and quality of service experience of an edge application is improved.

A wireless backhaul link is established between the IAB node and an IAB donor node via a first Narrow-Band Internet-of-Things (NB-IoT) carrier, in which the IAB donor node provides the IAB node with access to a wired backhaul connection that links to a core network of the wireless carrier network. One or more corresponding wireless backhaul links are further established between the IAB node and one or more additional IAB nodes via a one or more corresponding NB-IoT carriers. A wireless access link is then established between the IAB node and an NB-IoT user device or between the IAB donor node and the NB-IoT user device via a second NB-IoT carrier.

A wireless backhaul link is established between the IAB node and an IAB donor node via a first Narrow-Band Internet-of-Things (NB-IoT) carrier, in which the IAB donor node provides the IAB node with access to a wired backhaul connection that links to a core network of the wireless carrier network. One or more corresponding wireless backhaul links are further established between the IAB node and one or more additional IAB nodes via a one or more corresponding NB-IoT carriers. A wireless access link is then established between the IAB node and an NB-IoT user device or between the IAB donor node and the NB-IoT user device via a second NB-IoT carrier.

A mobile application development environment may be maintained in association with a computing platform. A request to produce a binary of a first mobile application may be processed. The binary and a package configurable to cause the binary to have code-sign credentials associated with a first organization when the binary is uploaded to a mobile application provider may be produced. The binary and the package may be provided to the first organization.