A central entity determines a physical cell identifier (PCI) change of an integrated access and backhaul (IAB) node from a first PCI to a second PCI and sends the second PCI to the IAB node. In response to receiving the second PCI from the central entity, the IAB node changes from using the first PCI to using the second PCI for the IAB node.

Provided are an electronic device and method for wireless communication, and a computer-readable storage medium. The electronic device comprises: a processing circuit, configured to: construct an interference overlapping diagram based on an interference/coexistence relationship between resource application systems within a management range, wherein a connection point of the interference overlapping diagram represents one or more resource application systems, and an edge of the interference overlapping diagram represents the fact that interference exists between the resource application systems represented by two connection points linked with the edge; remove one or more edges in the interference overlapping diagram so as to enable the interference overlapping diagram to meet a pre-determined condition after the removal; and carry out channel/resource allocation based on the adjusted interference overlapping diagram.

A communication resource allocation device (10) identifies a hazardous behavior that may cause a traffic accident and has occurred in each of monitoring target areas included in a communication area of a base station (20) in a past reference period, so as to determine a hazard level for each of the monitoring target areas. The communication resource allocation device (10) allocates communication resources to each of the monitoring target areas based on the determined hazard level. The communication resource allocation device (10) distributes information to a roadside device (30) and an in-vehicle device (40) in each of the monitoring target areas, using the allocated communication resources.

A communication resource allocation device (10) identifies a hazardous behavior that may cause a traffic accident and has occurred in each of monitoring target areas included in a communication area of a base station (20) in a past reference period, so as to determine a hazard level for each of the monitoring target areas. The communication resource allocation device (10) allocates communication resources to each of the monitoring target areas based on the determined hazard level. The communication resource allocation device (10) distributes information to a roadside device (30) and an in-vehicle device (40) in each of the monitoring target areas, using the allocated communication resources.

A data communication network includes data communication nodes configured to establish data connections with user equipment devices within a RF coverage area, imaging devices configured to provide image information for the RF coverage area, and an information handling system. The information handling system receives RF coverage information from the data communication nodes, receives first image information from the imaging devices, determines a first RF coverage map for the RF coverage area based upon the RF coverage information and the image information, provides a first bandwidth allocation to the data communication nodes based on the first RF coverage map, receives second image information from the imaging devices, determines that the first RF coverage map has changed to a second RF coverage map based upon a difference between the first image information and the second image information, and provides a second bandwidth allocation to the data communication nodes based on the second RF coverage map.

A data communication network includes data communication nodes configured to establish data connections with user equipment devices within a RF coverage area, imaging devices configured to provide image information for the RF coverage area, and an information handling system. The information handling system receives RF coverage information from the data communication nodes, receives first image information from the imaging devices, determines a first RF coverage map for the RF coverage area based upon the RF coverage information and the image information, provides a first bandwidth allocation to the data communication nodes based on the first RF coverage map, receives second image information from the imaging devices, determines that the first RF coverage map has changed to a second RF coverage map based upon a difference between the first image information and the second image information, and provides a second bandwidth allocation to the data communication nodes based on the second RF coverage map.

Transfer learning based on prediction determines a similarity between a source base station and a target base station. Importance of parameters is determined and training is adjusted to respect the importance of parameters. A lack of historical data is compensated by selecting a base station as source base station which has a larger amount of historical data.

Systems and methods are provided for opportunistic spatial reuse. In various embodiments, the disclosed systems and methods provide for mechanisms for enabling and disabling spatial reuse in a wireless network as appropriate based on the deployment of the wireless network. In some embodiments, spatial reuse can be enabled and disabled based on various factors, such as channel utilization. In some embodiments, spatial reuse can be enabled and disabled as appropriate for various types of traffic in a wireless network. For example, spatial reuse can be enabled and disabled for downlink traffic (e.g., traffic from an access point to a client device), for uplink traffic (e.g., traffic from a client device to an access point), for multicast or broadcast traffic (e.g., traffic distributed to multiple recipients), or for certain modes of transmission (e.g., single user beamformed transmission, Dual Carrier Modulated transmission).

Systems and methods are provided for opportunistic spatial reuse. In various embodiments, the disclosed systems and methods provide for mechanisms for enabling and disabling spatial reuse in a wireless network as appropriate based on the deployment of the wireless network. In some embodiments, spatial reuse can be enabled and disabled based on various factors, such as channel utilization. In some embodiments, spatial reuse can be enabled and disabled as appropriate for various types of traffic in a wireless network. For example, spatial reuse can be enabled and disabled for downlink traffic (e.g., traffic from an access point to a client device), for uplink traffic (e.g., traffic from a client device to an access point), for multicast or broadcast traffic (e.g., traffic distributed to multiple recipients), or for certain modes of transmission (e.g., single user beamformed transmission, Dual Carrier Modulated transmission).

A method for activation or deactivation, for a terminal, of a virtual subset of a telecommunications network referred to as a “network slice”, dedicated to a service. The telecommunications network includes a plurality of network slices. The method includes: acquiring at least one piece of context data of a user; and activating or deactivating at least one network slice among the plurality of network slices on the basis of the previously acquired piece of context data.