This application provides a network configuration method and device, applied to a mobile device. Compared with the conventional technology, in the device network configuration method provided in this application, a user can download and install a network configuration application as required, and an integrated operation for device network configuration is implemented, thereby reducing network configuration operation steps and network configuration time, implementing integration of network configuration application download and network configuration, and further improving user experience.

This application provides a network configuration method and device, applied to a mobile device. Compared with the conventional technology, in the device network configuration method provided in this application, a user can download and install a network configuration application as required, and an integrated operation for device network configuration is implemented, thereby reducing network configuration operation steps and network configuration time, implementing integration of network configuration application download and network configuration, and further improving user experience.

Disclosed are a communication technique for merging, with IoT technology, a 5G communication system for supporting a data transmission rate higher than that of a 4G system; and a system therefor. The present disclosure can be applied to intelligent services (for example, smart home, smart building, smart city, smart car or connected car, health care, digital education, retail, security, and safety-related services, and the like) on the basis of 5G communication technology and IoT-related technology. The present invention relates to a method and device for managing transmission beams of a terminal in a 5G system.

Disclosed are a communication technique for merging, with IoT technology, a 5G communication system for supporting a data transmission rate higher than that of a 4G system; and a system therefor. The present disclosure can be applied to intelligent services (for example, smart home, smart building, smart city, smart car or connected car, health care, digital education, retail, security, and safety-related services, and the like) on the basis of 5G communication technology and IoT-related technology. The present invention relates to a method and device for managing transmission beams of a terminal in a 5G system.

Systems and methods for building management utilizing adaptive edge processing are disclosed. The building system can store gateway components on storage devices. The gateway components can facilitate communication with a cloud platform and facilitate communication with a physical building device. The building system can identify a computing system of the building that is in communication with the physical building device. The physical building device can store one or more data samples. The building system can deploy the gateway components to the computing system responsive to identifying that the computing system is in communication with the physical building device. The gateway components can cause the computing system to communicate with the physical building device to receive the one or more data samples and cause the computing system to communicate the one or more data samples to the cloud platform.

A method including receiving, by a first device from a second device in a mesh network, a first status message indicating that the second device is operating in the mesh network as an entry device with respect to the first device or that the first device is operating in the mesh network as an exit device with respect to the second device such that data communicated by the second device outside the mesh network is routed via the first device; and selecting, by the first device based at least in part on the first status message, a third device in the mesh network as an exit device with respect to the first device such that data communicated by the first device outside the mesh network is routed via the third device, the third device being different from the second device. Various other aspects are contemplated.

In one embodiment, a method comprises determining which functional splits between processing performed in a baseband controller and processing performed in a remote unit are supported by each remote unit served by the baseband controller. The method further comprises determining at least one functional split in the processing performed in the baseband controller and the processing performed in the remote units to use. The method further comprises, for each said at least one functional split and each remote unit associated with that functional split, configuring the processing performed in the baseband controller and the processing performed in that remote unit are configured to use that functional split and configuring a respective interface between the baseband controller and that remote unit are configured for communicating front-haul data therebetween using that functional split.

A host can include a programmable network interface card (NIC) or “Smart NIC” which accesses host-local drives hidden from a host processor. One configuration can include a switch with a one logical partition including the NIC as a root complex (RC) and the local drives as end points (EPs), and with another logical partition including the host processor as an RC and the NIC as an EP. A second configuration can include the NIC and switch directly connected to the host processor with an access control component (ACC) configured on switch ports connected to the local drives. A third configuration can include the NIC and local drives directly connected to the host processor with the ACC configured on host processor ports connected to the local drives. The NIC can use a multi-layer driver to communicate with the ACC and local drives hidden behind the ACC.

A host can include a programmable network interface card (NIC) or “Smart NIC” which accesses host-local drives hidden from a host processor. One configuration can include a switch with a one logical partition including the NIC as a root complex (RC) and the local drives as end points (EPs), and with another logical partition including the host processor as an RC and the NIC as an EP. A second configuration can include the NIC and switch directly connected to the host processor with an access control component (ACC) configured on switch ports connected to the local drives. A third configuration can include the NIC and local drives directly connected to the host processor with the ACC configured on host processor ports connected to the local drives. The NIC can use a multi-layer driver to communicate with the ACC and local drives hidden behind the ACC.

A service management system communicates via wide area network with gateway devices located at respective user premises. The service management system remotely manages delivery of application services, which can be voice controlled, by a gateway, e.g. by selectively activating/deactivating service logic modules in the gateway. The service management system also may selectively provide secure communications and exchange of information among gateway devices and among associated endpoint devices. An exemplary service management system includes a router connected to the network and one or more computer platforms, for implementing management functions. Examples of the functions include a connection manager for controlling system communications with the gateway devices, an authentication manager for authenticating each gateway device and controlling the connection manager and a subscription manager for managing applications services and/or features offered by the gateway devices. A service manager, controlled by the subscription manager, distributes service specific configuration data to authenticated gateway devices.