Each of data receiving devices 20 includes a receiver 22 configured to receive data from a data providing device 10, and a transmitter 21 configured to transmit throughput information indicating a current position and a throughput, to the data providing device 10. The data providing device 10 includes: a receiver 11 configured to receive pieces of the throughput information; a planning unit 12 configured to, on the basis of the received pieces of throughput information, determine preceding data receiving devices 20 existing at positions preceding the current position of a target data receiving device 20 on the same route, and generate a data providing plan for the target data receiving device 20 on the basis of the throughputs of the preceding data receiving devices 20; and a transmitter 13 configured to provide data to the target data receiving device 20 in accordance with the generated data providing plan.

A base station for determining the status of overlap between cells without imposing unnecessary loads on a device that determines the status of overlap between the cells or on a terminal device has a first cell. The base station comprises a reception unit that receives information related to a second cell, from a first terminal device that communicates with the base station and that satisfies a condition related to the type of terminal device. The base station also comprises a determination unit that determines, on the basis of the information transmitted from the first terminal device, the status of overlap between the coverage range of the first cell and the coverage range of the second cell.

A base station for determining the status of overlap between cells without imposing unnecessary loads on a device that determines the status of overlap between the cells or on a terminal device has a first cell. The base station comprises a reception unit that receives information related to a second cell, from a first terminal device that communicates with the base station and that satisfies a condition related to the type of terminal device. The base station also comprises a determination unit that determines, on the basis of the information transmitted from the first terminal device, the status of overlap between the coverage range of the first cell and the coverage range of the second cell.

A method and apparatus for measuring and reporting cross-link interference are provided. The method includes receiving, from a base station (BS), a measurement configuration for the CLI, performing measurement on the configured measurement object based on the measurement configuration for the CLI and transmitting, to the BS, based on a measurement result of at least one of a resource from a plurality of resources for measuring the CLI of the configured measurement object exceeding a threshold, a measurement report for all of the plurality of resources for measuring the CLI of the configured measurement object whose measurement result exceeds the threshold.

A method and apparatus for measuring and reporting cross-link interference are provided. The method includes receiving, from a base station (BS), a measurement configuration for the CLI, performing measurement on the configured measurement object based on the measurement configuration for the CLI and transmitting, to the BS, based on a measurement result of at least one of a resource from a plurality of resources for measuring the CLI of the configured measurement object exceeding a threshold, a measurement report for all of the plurality of resources for measuring the CLI of the configured measurement object whose measurement result exceeds the threshold.

Flexible radio assignment with beamsteering antennas is provided by controlling a plurality of Access Points (APs) including steerable antennas to each transmit a first plurality of discovery frames at a first beamwidth; controlling the plurality of APs to steer the steerable antennas at a second beamwidth, less than the first beamwidth, to a plurality of steering angles; controlling the plurality of APs to each transmit a second plurality of discovery frames at each steering angle of the plurality of steering angles; determining an overlap in radio coverage among the plurality of APs based on the first plurality and the second plurality of discovery frames; and identifying redundant radios based on the overlap in radio coverage; and reassigning the redundant radios from use for client transmissions to a secondary role.

During operation, an electronic device may perform measurements associated with an environment. Then, the electronic device may create a model that represents the environment, where the model specifies a two-dimensional (2D) or a three-dimensional (3D) geometric layout of the environment and/or estimated parameters associated with radio-frequency properties of at least a portion of the environment. Moreover, the electronic device may design a wireless network for use in the environment, where the designing includes determining radio-frequency characteristics in a band of frequencies associated with the wireless network based at least in part on the model, and the wireless network is predicted to achieve one or more target communication-performance metrics. Next, the electronic device may provide the design information associated with the design that specifies the wireless network, where the design information includes one or more wireless-network components and one or more locations of the wireless-network components in the environment.

During operation, an electronic device may perform measurements associated with an environment. Then, the electronic device may create a model that represents the environment, where the model specifies a two-dimensional (2D) or a three-dimensional (3D) geometric layout of the environment and/or estimated parameters associated with radio-frequency properties of at least a portion of the environment. Moreover, the electronic device may design a wireless network for use in the environment, where the designing includes determining radio-frequency characteristics in a band of frequencies associated with the wireless network based at least in part on the model, and the wireless network is predicted to achieve one or more target communication-performance metrics. Next, the electronic device may provide the design information associated with the design that specifies the wireless network, where the design information includes one or more wireless-network components and one or more locations of the wireless-network components in the environment.

Examples described herein relate to generation of radio frequency (RF) plans for network deployments. Examples described herein may receive an input RF plan with modified set of features of a network deployment area. A first machine learning (ML) model generates an intermediate RF plan indicating candidate AR locations based on the modified set of features and a first set of parameters. A second ML model determines a network optimization score for the intermediate RF plan. Based on the optimization score, the first set of parameters are optimized. The first ML model generates an output RF plan indicating optimized AP locations based on the optimized first set of parameters and the modified set of features.

Examples described herein relate to generation of radio frequency (RF) plans for network deployments. Examples described herein may receive an input RF plan with modified set of features of a network deployment area. A first machine learning (ML) model generates an intermediate RF plan indicating candidate AR locations based on the modified set of features and a first set of parameters. A second ML model determines a network optimization score for the intermediate RF plan. Based on the optimization score, the first set of parameters are optimized. The first ML model generates an output RF plan indicating optimized AP locations based on the optimized first set of parameters and the modified set of features.