A network may transmit either beam deployment information or beam number information to a user equipment (UE) carried on a train and configured for operation in the millimeter wave band. The deployment information may include deployment related distance parameters or azimuth angle spread parameters. The beam number information may indicate a number of network beams associated with a current cell. The UE may determine a number of UE receive beams based on deployment information or the network-indicated number of network beams. The UE may transmit feedback to the network, indicating the number of UE receive beams. Alternatively, the network may send a configuration message indicating a first number of UE receive beams to the UE, which the UE may treat as an upper bound or lower bound in its determination of a desired number of UE receive beams. The UE may transmit the desired number to the network.

A network may transmit either beam deployment information or beam number information to a user equipment (UE) carried on a train and configured for operation in the millimeter wave band. The deployment information may include deployment related distance parameters or azimuth angle spread parameters. The beam number information may indicate a number of network beams associated with a current cell. The UE may determine a number of UE receive beams based on deployment information or the network-indicated number of network beams. The UE may transmit feedback to the network, indicating the number of UE receive beams. Alternatively, the network may send a configuration message indicating a first number of UE receive beams to the UE, which the UE may treat as an upper bound or lower bound in its determination of a desired number of UE receive beams. The UE may transmit the desired number to the network.

A radio wave status indicating apparatus is provided, the radio wave status indicating apparatus comprising: a radio wave intensity receiving unit that receives, from a communication apparatus, incoming radio wave intensity of the communication apparatus; a positional information acquiring unit that acquires positional information indicating a position of the communication apparatus; an expected value acquiring unit that acquires an expected value of incoming radio wave intensity at a position indicated by the positional information; a radio wave intensity comparing unit that compares the incoming radio wave intensity received by the radio wave intensity receiving unit with the expected value acquired by the expected value acquiring unit; and an indication information transmitting unit that transmits indication information based on a result of comparison by the radio wave intensity comparing unit to at least one of the communication apparatus and a communication terminal pre-registered in the communication apparatus.

A radio wave status indicating apparatus is provided, the radio wave status indicating apparatus comprising: a radio wave intensity receiving unit that receives, from a communication apparatus, incoming radio wave intensity of the communication apparatus; a positional information acquiring unit that acquires positional information indicating a position of the communication apparatus; an expected value acquiring unit that acquires an expected value of incoming radio wave intensity at a position indicated by the positional information; a radio wave intensity comparing unit that compares the incoming radio wave intensity received by the radio wave intensity receiving unit with the expected value acquired by the expected value acquiring unit; and an indication information transmitting unit that transmits indication information based on a result of comparison by the radio wave intensity comparing unit to at least one of the communication apparatus and a communication terminal pre-registered in the communication apparatus.

Systems and methods are described for automated sector creation in greenfield physical radiofrequency (RF) communication network infrastructures. For example, a network operator is granted licenses to use multiple spectrum blocks in multiple geographic regions for which the network operator does not currently have physical infrastructure. An RF network design defines a number of template antennas located at template site locations to meet a link budget over a target coverage area. For each template site location, embodiments can automatically compute sectors based on the associated template antennas and local spectrum licensing information. The computed sectors can effectively define a physical network deployment, including locations and configurations for sector antennas, by which the network operator can provide a desired quality of coverage to subscribers in the target coverage area.

Embodiments of this disclosure provide a method and apparatus for wireless network deployment and terminal device. The method includes: selecting a node needing to be currently deployed according to planned network information and deployed network information; calculating deployment quality of the node needing to be currently deployed at multiple test positions; and selecting a test position of highest deployment quality as a deployment position of the node needing to be currently deployed. With the embodiments of this disclosure, deployment quality of an actual deployment position of a wireless network node may be evaluated, such that actual deployment satisfies a requirement on network planning.

Embodiments of this disclosure provide a method and apparatus for wireless network deployment and terminal device. The method includes: selecting a node needing to be currently deployed according to planned network information and deployed network information; calculating deployment quality of the node needing to be currently deployed at multiple test positions; and selecting a test position of highest deployment quality as a deployment position of the node needing to be currently deployed. With the embodiments of this disclosure, deployment quality of an actual deployment position of a wireless network node may be evaluated, such that actual deployment satisfies a requirement on network planning.

Methods and systems are provided for adaptive management of antennas in a communication network comprising a complex array of both static and moving communication nodes (e.g., a network of moving things, which may be a vehicle network, a network of or including autonomous vehicles, etc.).

A method for forming a collaborative wireless sensor array comprising: connecting a plurality of wireless sensor nodes together, wherein each of the plurality of wireless sensor nodes wirelessly communicate with one another; collecting data by the plurality of wireless sensor nodes; forming metadata on the data collected by each of the plurality of wireless sensor nodes; sharing the data and metadata with the plurality of wireless sensor nodes; and fusing the data and metadata to perform a task.

A method for forming a collaborative wireless sensor array comprising: connecting a plurality of wireless sensor nodes together, wherein each of the plurality of wireless sensor nodes wirelessly communicate with one another; collecting data by the plurality of wireless sensor nodes; forming metadata on the data collected by each of the plurality of wireless sensor nodes; sharing the data and metadata with the plurality of wireless sensor nodes; and fusing the data and metadata to perform a task.