A controller and a control method for controlling an electronic equipment including a communication unit and a communication interface acquires from a cellular communication network theoretically divided into a plurality of slices in accordance with different service types, via a communication interface, an identifier allocated to at least one of the plurality of slices, specifies, based on the identifier, at least one provided service type which is a type of service provided by the cellular communication network, and transmits to a server via the communication interface, a report message including a network identifier indicating the cellular communication network and the at least one provided service type.

Novel tools and techniques are provided for implementing wireless functionality, and, more particularly, to methods, systems, and apparatuses for implementing faceplate-based wireless device functionality and wireless extension functionality. In various embodiments, one or more antennas, a power adapter, and at least one processor may be attached to an inner surface of a faceplate configured to be attached to a wall. The one or more antennas may be electrically coupled to the power adapter and communicatively coupled to the at least one processor. Alternatively, a wireless functionality device might include one or more antennas, a power adapter, and at least one processor. The wireless functionality device may be attached to an inner surface of a faceplate configured to be attached to a wall. The one or more antennas of the wireless functionality device may be electrically coupled to the power adapter and communicatively coupled to the at least one processor.

Novel tools and techniques are provided for implementing wireless functionality, and, more particularly, to methods, systems, and apparatuses for implementing faceplate-based wireless device functionality and wireless extension functionality. In various embodiments, one or more antennas, a power adapter, and at least one processor may be attached to an inner surface of a faceplate configured to be attached to a wall. The one or more antennas may be electrically coupled to the power adapter and communicatively coupled to the at least one processor. Alternatively, a wireless functionality device might include one or more antennas, a power adapter, and at least one processor. The wireless functionality device may be attached to an inner surface of a faceplate configured to be attached to a wall. The one or more antennas of the wireless functionality device may be electrically coupled to the power adapter and communicatively coupled to the at least one processor.

Methods, systems, and devices for wireless communications are described. A base station may receive positioning information for a first user equipment (UE), the first UE supporting sidelink communications via a sidelink interface with one or more roadside units. The base station may identify that a second UE is associated with the first UE, the association between the first UE and the second UE satisfying a threshold and the second UE supporting sidelink-assisted positioning. The base station may provide, to a network entity, a message indicating the positioning information for the first UE and identifying the first UE and the second UE.

Methods, systems, and devices for wireless communications are described. A base station may receive positioning information for a first user equipment (UE), the first UE supporting sidelink communications via a sidelink interface with one or more roadside units. The base station may identify that a second UE is associated with the first UE, the association between the first UE and the second UE satisfying a threshold and the second UE supporting sidelink-assisted positioning. The base station may provide, to a network entity, a message indicating the positioning information for the first UE and identifying the first UE and the second UE.

A method of a wireless communication device of acquiring position information. The method comprises transmitting, to a service-providing node, a request for service, receiving, from the service-providing node, a request for information indicating the position of the wireless communication device, receiving, from a network node, information indicating a position of the wireless communication device, the information having been provided with an indication of authenticity by the network node, and transmitting, to the service-providing node, the position information having been provided with an indication of authenticity.

Systems, methods, and computer readable media are disclosed for providing a hand free interaction between a user and a dispenser device. In embodiments of the invention, a mobile communication device and a beacon device associated with the dispenser device (or the dispenser device operating as a beacon device) may perform mutual authentication with a federated platform. Once the entities are authenticated, the user may be allowed to dispense the resource utilizing the dispenser device. Data associated with the interaction and related to the resource dispensed may be provided to the federated platform via the mobile communication device and the interaction data may be recorded. The federated platform may subsequently provide the interaction data to a resource provider to enable the resource provider to conduct a settlement process.

A wireless network device comprises a wireless signal driver, an application-driver framework that includes a bidirectional interface and an application interface. The application-driver framework is configured for application-agnostic and driver-agnostic communication. The bidirectional interface communicatively couples the wireless signal driver to the application-driver framework. The bidirectional interface includes an abstraction layer via which driver-agnostic command signals and driver-agnostic event signals are communicated with the application-driver framework and via which driver-specific command signals and driver-specific event signals are communicated with the wireless signal driver. The application interface is configured to interface with applications and with the application-driver framework. The application interface is configured to communicate application-agnostic command signals and application-agnostic event signals with the application-driver framework and to communicate application-specific event signals and application-specific command signals with the one or more applications and the application-driver framework.

A wireless network device comprises a wireless signal driver, an application-driver framework that includes a bidirectional interface and an application interface. The application-driver framework is configured for application-agnostic and driver-agnostic communication. The bidirectional interface communicatively couples the wireless signal driver to the application-driver framework. The bidirectional interface includes an abstraction layer via which driver-agnostic command signals and driver-agnostic event signals are communicated with the application-driver framework and via which driver-specific command signals and driver-specific event signals are communicated with the wireless signal driver. The application interface is configured to interface with applications and with the application-driver framework. The application interface is configured to communicate application-agnostic command signals and application-agnostic event signals with the application-driver framework and to communicate application-specific event signals and application-specific command signals with the one or more applications and the application-driver framework.

Embodiments of the present disclosure relate to a method, an electronic device, and a computer program product for application migration. The method includes determining an application used by a terminal device if it is determined that the terminal device moves from a first cell provided by a first network device to a second cell provided by a second network device. The method also includes determining a migration strategy for the application, the migration strategy describing the migration of components of the application in a predetermined scenario corresponding to the application. The method also includes determining migration information of components in an initial edge node associated with the first network device to a target edge node associated with the second network device based on the migration strategy, the migration information at least indicating whether the components in the initial edge node are to be migrated to the target edge node.