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.

The present invention relates a system and a method for optimizing Physical Cell ID (PCI) assignment in a wireless communication network such as an Open-Radio Access Network (O-RAN) (100). The method includes deploying an optimization service in an rApp (104) and registering the optimization service as a PCI-rApp within a Service Management and Orchestration Framework (SMO) (102), assigning a listing of unique predefined PCIs to operating cells of a selected range after satisfying one or more constraints and concluding that the procedure has been successful if the assignment of the PCI to each operating cell completes without using more than the listing of unique predefined PCIs.

Methods and systems for artificial intelligence (AI)-based communications are disclosed. At a second node, a task request is transmitted to a first node, the task request requiring configuration of at least one of a wireless communication functionality or a local AI model at the second node. A first set of configuration information is received from the first node, including a set of model parameters for the local AI model. The local AI model is configured by the set of model parameters to generate inference data including at least one inferred control parameter for configuring the second node for wireless communication.

Methods and systems for artificial intelligence (AI)-based communications are disclosed. At a second node, a task request is transmitted to a first node, the task request requiring configuration of at least one of a wireless communication functionality or a local AI model at the second node. A first set of configuration information is received from the first node, including a set of model parameters for the local AI model. The local AI model is configured by the set of model parameters to generate inference data including at least one inferred control parameter for configuring the second node for wireless communication.

Examples of the present disclosure describe systems and methods for locating an optimal installation location for an over-the-air (OTA) antenna. In some example aspects, the system described herein may receive a list of preferred local channels and/or programs from a user. The system may then compare those channels and/or programs to at least one database that comprises channel frequencies based on a user's geolocation (e.g., GPS coordinates, address, zip code, etc.). Based on the comparison of the preferred channels and/or programs, the system may suggest a certain installation location of an OTA antenna. The system may evaluate broadcast signals received by the OTA antenna to determine the strength of the signals at the present OTA antenna location. The results of the channel feedback analysis may be displayed in real-time (or near real-time) on a mobile device, indicating to the user if the present location is an optimal installation location.

Examples of the present disclosure describe systems and methods for locating an optimal installation location for an over-the-air (OTA) antenna. In some example aspects, the system described herein may receive a list of preferred local channels and/or programs from a user. The system may then compare those channels and/or programs to at least one database that comprises channel frequencies based on a user's geolocation (e.g., GPS coordinates, address, zip code, etc.). Based on the comparison of the preferred channels and/or programs, the system may suggest a certain installation location of an OTA antenna. The system may evaluate broadcast signals received by the OTA antenna to determine the strength of the signals at the present OTA antenna location. The results of the channel feedback analysis may be displayed in real-time (or near real-time) on a mobile device, indicating to the user if the present location is an optimal installation location.

A data communication network includes a data communication node, imaging devices, and an information handling system. The data communication node establishes a data connection with a user equipment device within a RF coverage area associated with the data communication node. The imaging devices provide image information for the RF coverage area. The information handling system receives the image information, synthesizes a 3D map of the RF coverage area based upon the image information, receives coverage information from the data communication node, and correlates the coverage information with the 3D map to generate a coverage map of the RF coverage area. The coverage map predicts an obstacle to the data connection within the RF coverage area.

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.

A method may include identifying, in a network, a location of a Fifth Generation (5G) node and determining, based on the location of the 5G node and capabilities associated with the 5G node, a number of areas around the 5G node, wherein each area corresponds to a bin. The method may also include identifying, in at least some of the of bins, candidate anchor nodes for the 5G node and ranking the candidate anchor nodes based on parameters associated with the candidate anchor nodes. The method may further include selecting, for the 5G node, an anchor node from the candidate anchor nodes based on the ranking.