A system and method for operation of a user equipment (UE) to determine a cellular network bottleneck in a downlink channel, and an apparatus for use in a UE for determining the same. A UE may determine a burst of network traffic from network traffic received from the cellular network during a series of transmission time intervals. The UE may analyze resource allocations to the UE during the burst to determine an extent to which the cellular network is busy. The UE may determine that the cellular network is experiencing a bottleneck based at least in part on the analysis of the resource allocations to the UE in the burst.

Embodiments of the present invention provide a cell clustering method and a base station. The method includes: obtaining initial information, where the initial information is used to indicate information about a handover between a serving cell and a neighboring cell or information about interference between a serving cell and a neighboring cell, the neighboring cell is a cell adjacent to the serving cell, and the serving cell is a cell in which first user equipment UE is located; obtaining an evaluation indicator of interference between the serving cell and the neighboring cell according to the initial information; and clustering the serving cell and the neighboring cell according to the interference evaluation indicator. The cell clustering method and the base station provided in the embodiments of the present invention can enhance performance of a communications system.

Embodiments of the present invention provide a cell clustering method and a base station. The method includes: obtaining initial information, where the initial information is used to indicate information about a handover between a serving cell and a neighboring cell or information about interference between a serving cell and a neighboring cell, the neighboring cell is a cell adjacent to the serving cell, and the serving cell is a cell in which first user equipment UE is located; obtaining an evaluation indicator of interference between the serving cell and the neighboring cell according to the initial information; and clustering the serving cell and the neighboring cell according to the interference evaluation indicator. The cell clustering method and the base station provided in the embodiments of the present invention can enhance performance of a communications system.

A method and system for dynamically controlling connection-request transmission in a cell provided by an access node, the access node supporting access attempts by user equipment devices (UEs), each access attempt including the UE engaging in random access signaling with the access node and the UE then engaging in up to a maximum allowed number of connection-request transmissions to the access node in an effort to ensure successful receipt by the access node of a connection request from the UE, where an access block occurs if the access node does not successfully receive connection-request transmission from the UE through the maximum allowed number connection-request transmissions. An example method includes (i) determining an extent to which the cell has experienced such access blocks and (ii) using the determined extent as a basis to dynamically set a maximum allowed number of connection-request transmissions per access attempt in the cell.

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.

An interactive software-based network design tool that may be used to simulate and view the operation of a wireless mesh device network used in a process plant, such as a wireless HART device network, allows a user to create a model of a wireless network, input several design requirements, and automatically generate and view communication routes and schedules for the wireless network. The network design tool provides an interactive graphic interface for the addition, removal, and positioning of nodes and devices within the wireless network and a menu including several interactive screens for specifying threshold values, network topology selections, routing preferences, and other configuration parameters related to generating and optimizing communication routes and schedules within the wireless mesh network. The network design tool automatically applies a set of optimization rules along with the parameters input by user to the network model in order to generate efficient network configuration data.

An interactive software-based network design tool that may be used to simulate and view the operation of a wireless mesh device network used in a process plant, such as a wireless HART device network, allows a user to create a model of a wireless network, input several design requirements, and automatically generate and view communication routes and schedules for the wireless network. The network design tool provides an interactive graphic interface for the addition, removal, and positioning of nodes and devices within the wireless network and a menu including several interactive screens for specifying threshold values, network topology selections, routing preferences, and other configuration parameters related to generating and optimizing communication routes and schedules within the wireless mesh network. The network design tool automatically applies a set of optimization rules along with the parameters input by user to the network model in order to generate efficient network configuration data.

The present invention provides a network coverage planning method and apparatus of an evolution communication system, wherein the method includes: obtaining the theoretical coverage parameter of a single base station of the evolution communication system by link budget; obtaining the theoretical coverage parameter of an entire network of the evolution communication system by network stimulation; calculating a reception level value of the evolution communication system under the wireless environment of a current network communication system in the same planning area to estimate a simulative measured coverage parameter of the evolution communication system; and planning the coverage parameter of the entire network of the evolution communication system according to the theoretical coverage parameter of the single base station, the theoretical coverage parameter of the entire network and the simulative measured coverage parameter.

The present invention provides a network coverage planning method and apparatus of an evolution communication system, wherein the method includes: obtaining the theoretical coverage parameter of a single base station of the evolution communication system by link budget; obtaining the theoretical coverage parameter of an entire network of the evolution communication system by network stimulation; calculating a reception level value of the evolution communication system under the wireless environment of a current network communication system in the same planning area to estimate a simulative measured coverage parameter of the evolution communication system; and planning the coverage parameter of the entire network of the evolution communication system according to the theoretical coverage parameter of the single base station, the theoretical coverage parameter of the entire network and the simulative measured coverage parameter.