Network planning based on collected crowd-sourced access point quality and selection data can optimize access point frequency and/or bandwidth selection. A cloud-based application can be utilized in conjunction with a mobile device to build a database of access point quality and thresholds suitable for real-time and other jitter-sensitive services. The mobile device jitter measurements and selection thresholds can be collected at a cloud platform, which creates an access point performance and selection threshold profile from which the network can facilitate access point frequency and/or bandwidth selections.

Radio link coverage mapping systems and related techniques are provided to improve the operation of unmanned mobile sensor or survey platforms. A radio or communication link coverage mapping system includes a logic device configured to communicate with a communication module and a position sensor coupled to a mobile platform, where the communication module is configured to establish a wireless communication link with a base station associated with the mobile platform and the position sensor is configured to provide a position of the mobile platform as it maneuvers within a survey area. The logic device determines communication link quality data associated with the wireless communication link as the mobile platform maneuvers within the survey area, receives corresponding position data, and generates corresponding communication coverage information, which may be used to generate a radio link coverage map.

Radio link coverage mapping systems and related techniques are provided to improve the operation of unmanned mobile sensor or survey platforms. A radio or communication link coverage mapping system includes a logic device configured to communicate with a communication module and a position sensor coupled to a mobile platform, where the communication module is configured to establish a wireless communication link with a base station associated with the mobile platform and the position sensor is configured to provide a position of the mobile platform as it maneuvers within a survey area. The logic device determines communication link quality data associated with the wireless communication link as the mobile platform maneuvers within the survey area, receives corresponding position data, and generates corresponding communication coverage information, which may be used to generate a radio link coverage map.

Techniques for modelling a radio network in a geographic region utilizing shared spectra are disclosed. Population data is obtained for the geographic region. A number of radios per channel in the geographic region, N′, is determined. Candidate geographic location for radios in the geographic region are determined. For every channel in the shared spectra, at least one of a static dataset and a dynamic dataset is determined. At least one set of output data, that is a statistical characterization of the radio network, is generated using at least one of the static dataset and the dynamic dataset, to aid in design of the radio network.

Techniques for modelling a radio network in a geographic region utilizing shared spectra are disclosed. Population data is obtained for the geographic region. A number of radios per channel in the geographic region, N′, is determined. Candidate geographic location for radios in the geographic region are determined. For every channel in the shared spectra, at least one of a static dataset and a dynamic dataset is determined. At least one set of output data, that is a statistical characterization of the radio network, is generated using at least one of the static dataset and the dynamic dataset, to aid in design of the radio network.

A method for configuring a plurality of wireless access point devices, executed by a configuration device, in a communication network, includes: gathering first information items representing usage capacities of the wireless access point devices; gathering second information items representing the use or usage capacities of electronic devices connected to one or more wireless access point devices; gathering third information items representing a use, by at least one wireless access point device outside the network, of a communication channel that can be used by at least one wireless access point device; considering a plurality of configuration scenarios corresponding to a combination of a frequency band and a bandwidth; establishing a theoretical performance score for each of the scenarios, the score established at least with respect to said first, second and third information items and configuring the wireless access point devices in accordance with the configuration scenario having the best performance score.

Provided is a method of performing network listening (NL) for a radio unit (RU) in a Cloud-Radio Access Network (C-RAN) structure base station in which a certain RU distinguishes and automatically detects signals of neighboring RUs through NL in a C-RAN structure base station to thereby enable optimization and automation of configuration setting of multiple cells and multiple RUs. The method of performing NL for a RU in a base station having a structure of a C-RAN, performed between a C-RAN base station body and a RU in the C-RAN supporting multiple cells and multiple RUs, includes the steps of: (a) searching for, by the C-RAN base station body, RU configuration (a cell-RU combination) information constructed therein to instruct an RU that is to perform NL to perform the NL while instructing a RU using the same physical cell identifier (PCI) as the RU that is to perform the NL to turn off a radio frequency (RF) transmit (Tx) output thereof during performance of the NL of the RU that is to perform NL; (b) performing, by the RU instructed to perform the NL, the NL with a RF transmit (Tx) output thereof turned off; (c) turning on, by the RU instructed to perform the NL, the RF transmit (Tx) output thereof after completion of the performance of the NL while reporting a result of the performance of the NL and completion of the NL to the C-RAN base station body; and (d) instructing, by the C-RAN base station body, the RU using the same PCI to turn on the RF transmit (Tx) output thereof.

Provided is a method of performing network listening (NL) for a radio unit (RU) in a Cloud-Radio Access Network (C-RAN) structure base station in which a certain RU distinguishes and automatically detects signals of neighboring RUs through NL in a C-RAN structure base station to thereby enable optimization and automation of configuration setting of multiple cells and multiple RUs. The method of performing NL for a RU in a base station having a structure of a C-RAN, performed between a C-RAN base station body and a RU in the C-RAN supporting multiple cells and multiple RUs, includes the steps of: (a) searching for, by the C-RAN base station body, RU configuration (a cell-RU combination) information constructed therein to instruct an RU that is to perform NL to perform the NL while instructing a RU using the same physical cell identifier (PCI) as the RU that is to perform the NL to turn off a radio frequency (RF) transmit (Tx) output thereof during performance of the NL of the RU that is to perform NL; (b) performing, by the RU instructed to perform the NL, the NL with a RF transmit (Tx) output thereof turned off; (c) turning on, by the RU instructed to perform the NL, the RF transmit (Tx) output thereof after completion of the performance of the NL while reporting a result of the performance of the NL and completion of the NL to the C-RAN base station body; and (d) instructing, by the C-RAN base station body, the RU using the same PCI to turn on the RF transmit (Tx) output thereof.

The disclosure provides a base station and a method for optimizing the coverage of a self-defined network. The method includes: receiving a measurement report from user equipment; in response to determining that the measurement report indicates that a neighboring first base station is present, sending a member tracking message to the first base station; determining whether the first base station belongs to any other base station group based on a member tracking response from the first base station; in response to determining that the first base station does not belong to any other base station group, adding the first base station to a base station group managed by the base station; and in response to determining that the member tracking response indicates that the first base station belongs to another base station group, merging the base station group and the another base station group.

The disclosure provides a base station and a method for optimizing the coverage of a self-defined network. The method includes: receiving a measurement report from user equipment; in response to determining that the measurement report indicates that a neighboring first base station is present, sending a member tracking message to the first base station; determining whether the first base station belongs to any other base station group based on a member tracking response from the first base station; in response to determining that the first base station does not belong to any other base station group, adding the first base station to a base station group managed by the base station; and in response to determining that the member tracking response indicates that the first base station belongs to another base station group, merging the base station group and the another base station group.