An electronic device included in a network enhances the configuring of other electronic devices in the network. The electronic device includes a network interface, a non-transitory memory having instructions stored thereon, and a hardware processor. The hardware processor is configured to execute the instructions to transmit a first set of configuration data to another electronic device in the network, receive a message that the other electronic device was successfully configured using the first set of configuration data, and in response to the message transmit one or more next sets of configuration data to the other electronic device. Moreover, the hardware processor is configured to execute the instructions to receive a message that the other electronic device was not successfully configured using the first set of configuration data or the one or more next sets of configuration data and implement remedial action to address the unsuccessful configuration.

An electronic device included in a network enhances the configuring of other electronic devices in the network. The electronic device includes a network interface, a non-transitory memory having instructions stored thereon, and a hardware processor. The hardware processor is configured to execute the instructions to transmit a first set of configuration data to another electronic device in the network, receive a message that the other electronic device was successfully configured using the first set of configuration data, and in response to the message transmit one or more next sets of configuration data to the other electronic device. Moreover, the hardware processor is configured to execute the instructions to receive a message that the other electronic device was not successfully configured using the first set of configuration data or the one or more next sets of configuration data and implement remedial action to address the unsuccessful configuration.

Methods, systems, and apparatus, including computer programs encoded on a computer storage medium, for implementing a network feature tester are disclosed. In one aspect, a method includes the actions of selecting computing devices that are configured to communicate with a wireless carrier network based on the computing devices having a common characteristic. The actions further include identifying a subset of the computing devices that are likely to communicate with a same base station of the wireless carrier network during a first period of time and a second period of time. The actions further include determining first monitoring data during the first period of time. The actions further include adjusting a characteristic of the same base station. The actions further include determining second monitoring data during the second period of time. The actions further include determining an effect that adjusting the characteristic has on the wireless carrier network.

Methods, systems, and apparatus, including computer programs encoded on a computer storage medium, for implementing a network feature tester are disclosed. In one aspect, a method includes the actions of selecting computing devices that are configured to communicate with a wireless carrier network based on the computing devices having a common characteristic. The actions further include identifying a subset of the computing devices that are likely to communicate with a same base station of the wireless carrier network during a first period of time and a second period of time. The actions further include determining first monitoring data during the first period of time. The actions further include adjusting a characteristic of the same base station. The actions further include determining second monitoring data during the second period of time. The actions further include determining an effect that adjusting the characteristic has on the wireless carrier network.

A device may receive data identifying a quantity of wireless network devices, distance data identifying distances from the wireless network devices to a geographical location, data identifying signal strengths of the wireless network devices, carrier data identifying wireless and wireline carriers for the wireless network devices, or path data identifying wireline paths for the wireless network devices and wireline network devices. The device may assign scores to the quantity, the distance data, the signal strengths, the carrier data, or the path data to generate scores, and may combine the scores to generate a diversity risk score. The device may compare the diversity risk score to a diversity risk threshold scale and may determine whether the diversity risk score satisfies thresholds of the diversity risk threshold scale based on the comparison. The device may perform actions based on whether the diversity risk score satisfies the thresholds.

Methods, systems, and devices for wireless communications are described. A device may receive an indication of a subcarrier spacing (SCS) for communications in a plurality of transmission time intervals (TTIs), where a TTI include a set of symbols, a corresponding set of cyclic prefixes, and a padding duration. The device may receive a control signal indicating a configuration for the padding duration, at least a portion of which may be reallocated as one or more additional symbols with corresponding one or more additional cyclic prefixes. In some examples, the one or more additional cyclic prefixes and at least a first portion of the set of cyclic prefixes may be reduced in duration in comparison with a remaining portion of the set of cyclic prefixes. The device may communicate during the padding duration using the one or more additional symbols and the corresponding one or more additional cyclic prefixes.

A highly sensitive RADAR system comprising a plurality of ground stations, where each ground station includes a plurality of ground-based directional antennae, each ground-based directional antenna having a beam width associated with a particular area of the sky above the ground station and, for each ground-based directional antenna, a least one software defined radio is coupled to the directional antenna in such a manner as to enable the ground-based directional antenna to transmit radfrequency signals generated by the software defined radio at one or more frequencies and to provide to the software defined radfrequency signals received by the ground-based directional antenna at one or more frequencies; and where each of a plurality of the ground stations is configured to transmit a radfrequency signal into a specific defined area of space in such a manner that the various transmitted radio signals will arrive in the defined area of space at substantially the same time; and wherein, each of the plurality of ground stations are further configured to detect reflected radio signals from an object within the defined area of space; and wherein the system further includes a processor for processing any reflected signals received by is the plurality of ground stations to identify the presence of objects within the defined space.

Examples provide a network testing solution using a remote-controlled testing device. A test device includes a computing device for executing network performance testing logic and a cellular device. The test device controls the cellular device via a series of commands issued to the cellular device by the computing device. The test device is placed onto or inside a vehicle. As the vehicle moves through a geographical area, the test device automatically and autonomously performs network testing operations. The test data generated during the test is periodically uploaded to a central controller. The central controller aggregates test data received from a plurality of test devices assigned to a plurality of vehicles for a given campaign. The aggregated test data is analyzed and filtered to generate performance test results. A user can dynamically set up each campaign and assign test devices and vehicles to each campaign using a graphical user interface.

An apparatus for an application function (AF) includes a communication interface and a processor operably coupled to the communication interface. The processor is configured to receive, via the communication interface, network slice identification and media service identification across slices for a media service. The processor is also configured to manage a service corresponding to the network slice identification to a user equipment (UE). The processor is further configured to receive, via the communication interface, expected media service policy information from the UE. In addition, the processor is configured to identify policy information corresponding to each of the slices, respectively. The processor is also configured to transmit, via the communication interface, the policy information corresponding to each of the slices, respectively.

An apparatus for an application function (AF) includes a communication interface and a processor operably coupled to the communication interface. The processor is configured to receive, via the communication interface, network slice identification and media service identification across slices for a media service. The processor is also configured to manage a service corresponding to the network slice identification to a user equipment (UE). The processor is further configured to receive, via the communication interface, expected media service policy information from the UE. In addition, the processor is configured to identify policy information corresponding to each of the slices, respectively. The processor is also configured to transmit, via the communication interface, the policy information corresponding to each of the slices, respectively.