Low-performing cells, serving a telecom deployment in a given geographical area, are commonly identified by the telecom operators based on one or more Network KPIs computed for each of the cells being part of the deployment. However, most of these KPIs describe the overall state of affairs of the cell without any insight into the user usage profile of the cell. The present disclosure proposes a novel method to adjust the network KPIs based on scores of the macro cell or the small cell (101) with the user usage profile of the cell to obtain the user correlated network scores of the cells and prioritize the low-performing cells in the network in order of degree of impact on users and their usage. Another aspect of this disclosure is that it shall predict and compute a realistic user score to get predictive insights into user profiles for solutions and preventive measures.

Low-performing cells, serving a telecom deployment in a given geographical area, are commonly identified by the telecom operators based on one or more Network KPIs computed for each of the cells being part of the deployment. However, most of these KPIs describe the overall state of affairs of the cell without any insight into the user usage profile of the cell. The present disclosure proposes a novel method to adjust the network KPIs based on scores of the macro cell or the small cell (101) with the user usage profile of the cell to obtain the user correlated network scores of the cells and prioritize the low-performing cells in the network in order of degree of impact on users and their usage. Another aspect of this disclosure is that it shall predict and compute a realistic user score to get predictive insights into user profiles for solutions and preventive measures.

Methods and apparatus for processing and reconciling data traffic utilization information from a variety of sources including client devices and service provider networks are described. The methods take into consideration that wireless devices tracking usage data may not accurately reflect the amount of usage measured by network devices. This may be because of overhead the client devices are not aware of or because different measurement techniques or accounting metrics are used by the service provider network. The methods and apparatus may and sometimes do take into consideration that while some client devices, e.g., android devices, may trach and report usage aid/or location information through the use of an application which provides such information to the network service provider, such information may not be readily available from other devices such Apple iOS devices. The described data tracking and location assignment methods are used in some embodiments to determine base station placement.

Methods and apparatus for processing and reconciling data traffic utilization information from a variety of sources including client devices and service provider networks are described. The methods take into consideration that wireless devices tracking usage data may not accurately reflect the amount of usage measured by network devices. This may be because of overhead the client devices are not aware of or because different measurement techniques or accounting metrics are used by the service provider network. The methods and apparatus may and sometimes do take into consideration that while some client devices, e.g., android devices, may trach and report usage aid/or location information through the use of an application which provides such information to the network service provider, such information may not be readily available from other devices such Apple iOS devices. The described data tracking and location assignment methods are used in some embodiments to determine base station placement.

A method (200) of configuring a telecommunications network (100), the method comprising the steps 5 of: identifying a User Equipment (UE) (110) utilizing the telecommunications network; ascertaining physical capability information associated with a user of the identified UE (220); determining a network configuration in dependence upon the ascertained physical capability information (240); and configuring a network connection for the identified UE according to the determined network configuration (250).

A method (200) of configuring a telecommunications network (100), the method comprising the steps 5 of: identifying a User Equipment (UE) (110) utilizing the telecommunications network; ascertaining physical capability information associated with a user of the identified UE (220); determining a network configuration in dependence upon the ascertained physical capability information (240); and configuring a network connection for the identified UE according to the determined network configuration (250).

Systems and methods model earth stations and other captive terrestrial sites as simulated cell sites in a radio access network (RAN) to identify potential cellular network interferers with the earth stations. A computing device selects an earth station within a geographic area of a RAN segment and model the earth station as a cell within the RAN segment, wherein the modeling creates a simulated earth station cell. The computing device obtains sector carrier data for cells in the RAN segment and scores, based on the sector carrier data, neighboring cells to the simulated earth station cell. The scoring indicates a level of potential interference of the neighboring cells with the earth station based on geo-spatial relevance. The computing device identifies projected mobility interference in neighboring cells to the earth station and provides prioritization recommendations for interference mitigation for the earth station based on the scoring and the identifying.

An access point that determines communication boundaries is described. During operation, the access point may receive one or more probe requests associated with the one or more electronic devices, where a given probe request may include an identifier of a given electronic device. Moreover, when the access point receives the given probe request, the access point may determine a signal strength associated with the given probe request and timestamps when the given probe request was received. Then, the access point may exchange probe-request information with one or more additional access points, where the probe-request information corresponds to received probe requests. Next, the access point may compare the probe-request information to determine the communication boundaries. For example, the communication boundaries may be determined by comparing the probe-request information for pairs of access points. Furthermore, the access point may identify neighboring access points based at least in part on the probe-request information.

An access point that determines communication boundaries is described. During operation, the access point may receive one or more probe requests associated with the one or more electronic devices, where a given probe request may include an identifier of a given electronic device. Moreover, when the access point receives the given probe request, the access point may determine a signal strength associated with the given probe request and timestamps when the given probe request was received. Then, the access point may exchange probe-request information with one or more additional access points, where the probe-request information corresponds to received probe requests. Next, the access point may compare the probe-request information to determine the communication boundaries. For example, the communication boundaries may be determined by comparing the probe-request information for pairs of access points. Furthermore, the access point may identify neighboring access points based at least in part on the probe-request information.

The present disclosure relates to a method and an apparatus for establishing a positioning network. The positioning network includes a data processing center and at least one reference station, and one node in the positioning network represents one reference station. The method includes: determining, if a first historical positioning network capable of forming a new positioning network with a newly added node exists in a network list of the data processing center, whether the newly added node forms the new positioning network with the first historical positioning network; and determining, if the network list does not exist in the data processing center, whether the newly added node is capable of forming a new positioning network with nodes in a first node information list. Before network real-time kinematic (RTK) is formed, a user can use a single-baseline RTK positioning service. The network RTK is formed once a networking condition is met. A positioning network is gradually established, requirements of users may be satisfied with less investment when there are fewer users in the early stage, and the network is gradually formed with the increase of users, so that more users can be covered by using fewer base stations.