A graphical user interface for use with one or more radios in a network can include any number of interfaces for providing access to features associated with one or more radios or the network.

In a connected vehicle environment, network connection parameters such as a network congestion window and bit rate are automatically adjusted dependent on a location of a vehicle in order to optimize network performance. A geospatial database stores learned relationships between network performance of a connected vehicle at different physical locations when configured in accordance with different network parameters. The vehicle can then adjust its network parameters dynamically dependent on its location. A vehicle may maintain multiple connections to different networks concurrently for transmitting duplicate data of a data stream, with the vehicle independently adjusting parameters associated with different networks to optimize performance.

In a connected vehicle environment, network connection parameters such as a network congestion window and bit rate are automatically adjusted dependent on a location of a vehicle in order to optimize network performance. A geospatial database stores learned relationships between network performance of a connected vehicle at different physical locations when configured in accordance with different network parameters. The vehicle can then adjust its network parameters dynamically dependent on its location. A vehicle may maintain multiple connections to different networks concurrently for transmitting duplicate data of a data stream, with the vehicle independently adjusting parameters associated with different networks to optimize performance.

Cellular communication network is managed by receiving at a computing device certain data specifying geolocation information of one or more user equipment in communication with one or more nodes of the cellular communication system. The computing device identifies a disruption in receipt of the periodic geolocation information, and uses the received geolocation information to at least partially define a location of a peripheral edge of a communication dead zone. The peripheral edge information is used to facilitate a dynamic modification or control of the cellular communication network and/or the user equipment.

Cellular communication network is managed by receiving at a computing device certain data specifying geolocation information of one or more user equipment in communication with one or more nodes of the cellular communication system. The computing device identifies a disruption in receipt of the periodic geolocation information, and uses the received geolocation information to at least partially define a location of a peripheral edge of a communication dead zone. The peripheral edge information is used to facilitate a dynamic modification or control of the cellular communication network and/or the user equipment.

Unmanned aerial vehicle drive testing and mapping of carrier signals is disclosed. An example method may include determining that an unmanned aerial vehicle is travelling on a flight route at an altitude for determination of network performance of a cellular network. The method may further include determining, using an antenna, signal diagnostics of the cellular network during travel of the unmanned aerial vehicle on the flight route. The method may conclude with transmitting the signal diagnostics of the cellular network to a service provider.

Unmanned aerial vehicle drive testing and mapping of carrier signals is disclosed. An example method may include determining that an unmanned aerial vehicle is travelling on a flight route at an altitude for determination of network performance of a cellular network. The method may further include determining, using an antenna, signal diagnostics of the cellular network during travel of the unmanned aerial vehicle on the flight route. The method may conclude with transmitting the signal diagnostics of the cellular network to a service provider.

In an embodiment, a method, for deploying an edge application server (EAS) is disclosed. The method includes receiving an EAS deployment request to create an EAS instance associated with an EASFunction class, identifying, based on the EAS deployment request, one or more requirements for the EAS instance, selecting an edge data network (EDN) based on the one or more requirements for the EAS instance, and creating a managed object instance (MOI) corresponding to the EAS deployment request.

In an embodiment, a method, for deploying an edge application server (EAS) is disclosed. The method includes receiving an EAS deployment request to create an EAS instance associated with an EASFunction class, identifying, based on the EAS deployment request, one or more requirements for the EAS instance, selecting an edge data network (EDN) based on the one or more requirements for the EAS instance, and creating a managed object instance (MOI) corresponding to the EAS deployment request.

A method of determining a location at which a movable base station is to be installed is provided. In the method, an information processing device performs first determination processing of determining a base station providing radio communication that does not satisfy a predetermined condition based on information of a radio signal of each base station, second determination processing of determining a number of virtual terminals to be set in a coverage area of the base station providing the radio communication that does not satisfy the predetermined condition based on the information of the radio signal of the base station, and third determination processing of determining the location at which the movable base station is to be installed based on a location of each virtual terminal set in the coverage area of the base station providing the radio communication that does not satisfy the predetermined condition.