Systems and methods are provided herein to dynamically and efficiently optimize network expansion of a network carrier based on UE data collected from a plurality of user equipment (UEs). The UE data is processed based on different computerized algorithms to locate optimal locations for adding a new access point to expand the network. Aspects herein are also directed to systems and methods for generating and displaying dynamic maps on graphical user interfaces (GUI) in accordance with aspects herein.

Systems and methods for telecommunications network coverage optimization are disclosed. The network coverage optimization system computes a usability index value for a geographic area using measured values of telecommunications network usability indicators. The telecommunications network usability indicators are related to network coverage (e.g., whether the user has enough bars and can make a call), quality of service (e.g., whether the speech and data quality are good), and data speed (e.g., the amount of buffering the user is experiencing). The telecommunications network usability indicators can be selected based on an importance rating associated with them. Then, for each geographic area, the network coverage optimization system computes a score value and a weight value for each selected telecommunications network usability indicator. Using the computed score values and the computed weight values, the network coverage optimization system computes a usability index value for the geographic area.

Systems and methods for telecommunications network coverage optimization are disclosed. The network coverage optimization system computes a usability index value for a geographic area using measured values of telecommunications network usability indicators. The telecommunications network usability indicators are related to network coverage (e.g., whether the user has enough bars and can make a call), quality of service (e.g., whether the speech and data quality are good), and data speed (e.g., the amount of buffering the user is experiencing). The telecommunications network usability indicators can be selected based on an importance rating associated with them. Then, for each geographic area, the network coverage optimization system computes a score value and a weight value for each selected telecommunications network usability indicator. Using the computed score values and the computed weight values, the network coverage optimization system computes a usability index value for the geographic area.

The present disclosure relates to converging a 5th-Generation (5G) communication system for supporting higher data rates beyond a 4th-Generation (4G) system with a technology for Internet of Things (IoT), and may be applied to intelligent services, such as smart home, smart building, smart city, smart car, connected car, health care, digital education, smart retail, security and safety services. A method according to disclosed aspects includes receiving a first control message including a first random access response window for a first cell group, receiving a second control message for adding a second cell group, including information on a second random access response window size for the second cell group, transmitting, on a cell of the second cell group, a random access preamble, and monitoring, on the cell of the second cell group, a random access response based on the second random access response window size for the second cell group.

The present disclosure relates to converging a 5th-Generation (5G) communication system for supporting higher data rates beyond a 4th-Generation (4G) system with a technology for Internet of Things (IoT), and may be applied to intelligent services, such as smart home, smart building, smart city, smart car, connected car, health care, digital education, smart retail, security and safety services. A method according to disclosed aspects includes receiving a first control message including a first random access response window for a first cell group, receiving a second control message for adding a second cell group, including information on a second random access response window size for the second cell group, transmitting, on a cell of the second cell group, a random access preamble, and monitoring, on the cell of the second cell group, a random access response based on the second random access response window size for the second cell group.

Disclosed herein is a system comprising a set of wireless communication nodes that are configured to operate as part of a wireless mesh network. Each respective wireless communication node may be directly coupled to at least one other wireless communication node via a respective short-hop wireless link, and at least a first pair of wireless nodes may be both (a) indirectly coupled to one another via a first communication path that comprises one or more intermediary wireless communication nodes and two or more short-hop wireless links and (b) directly coupled to one another via a first long-hop wireless link that provides a second communication path between the first pair of wireless communication nodes having a lesser number of hops than the first communication path. A fiber access point may be directly coupled to a first wireless communication node of the set of wireless communication nodes.

A method for dynamic and extensible creation of an extensible wireless network, using a set of drones that individually support server processes. The drones interact with one another, exchanging information, type of coverage, type and amount of throughput, location, etc. A control node connects to a wired network. The node operates a leader election protocol, captures state information from the drones, and positions/re-positions the drones as necessary. Drones are flown in to position and then engaged as necessary to stretch/adapt the coverage as necessary. The drone's power utilization is monitored and its coverage area modified as necessary to optimize power utilization. The control node performs drone-based coverage/power utilization computations, and attempts to apply the appropriate location assignments to provide maximum network coverage (extensibility) while also preserving drone-specific power (battery) utilization. The approach herein can be used to supplement existing networks during events, migrations of populations during work hours, etc.

A method for dynamic and extensible creation of an extensible wireless network, using a set of drones that individually support server processes. The drones interact with one another, exchanging information, type of coverage, type and amount of throughput, location, etc. A control node connects to a wired network. The node operates a leader election protocol, captures state information from the drones, and positions/re-positions the drones as necessary. Drones are flown in to position and then engaged as necessary to stretch/adapt the coverage as necessary. The drone's power utilization is monitored and its coverage area modified as necessary to optimize power utilization. The control node performs drone-based coverage/power utilization computations, and attempts to apply the appropriate location assignments to provide maximum network coverage (extensibility) while also preserving drone-specific power (battery) utilization. The approach herein can be used to supplement existing networks during events, migrations of populations during work hours, etc.

Disclosed in the present application are a cell selection method and apparatus, a device and a storage medium, relating to the field of communications. The method comprises: in an NTN scenario, a terminal performing cell selection according to first information, the first information comprising at least one of the following: location information of the terminal; the type of a satellite; a deployment scenario of the satellite; and a cell type of the satellite.

Disclosed in the present application are a cell selection method and apparatus, a device and a storage medium, relating to the field of communications. The method comprises: in an NTN scenario, a terminal performing cell selection according to first information, the first information comprising at least one of the following: location information of the terminal; the type of a satellite; a deployment scenario of the satellite; and a cell type of the satellite.