Systems and methods of managing a plurality of Wi-Fi networks via a cloud service include communicating to a plurality of access points in the plurality of Wi-Fi networks, wherein the plurality of access points are deployed in a location that includes any of a multi-dwelling unit (MDU), office space, retail space, mixed-use space, and common areas; providing end user management access to a plurality of end users each associated with one of the plurality of Wi-Fi networks; providing property manager management access to a property manager associated with the location and with any additional locations; and providing service provider management access to a service provider associated with the location.

Systems and methods of managing a plurality of Wi-Fi networks via a cloud service include communicating to a plurality of access points in the plurality of Wi-Fi networks, wherein the plurality of access points are deployed in a location that includes any of a multi-dwelling unit (MDU), office space, retail space, mixed-use space, and common areas; providing end user management access to a plurality of end users each associated with one of the plurality of Wi-Fi networks; providing property manager management access to a property manager associated with the location and with any additional locations; and providing service provider management access to a service provider associated with the location.

The present disclosure is directed to 3-D visualization of wireless signal propagation representing wireless signal strength and interference in 3-D space. The present technology can identify a plurality of access points (APs) in the 3-D space, determine a wireless signal strength for each of the plurality of APs, and determine an interference with the wireless signal strength of each of the plurality of APs, wherein the interference is caused by a neighboring AP of the plurality of APs in the 3-D space. The present technology can further present a 3-D visualization of a wireless signal propagation pattern representing the wireless signal strength from each of the plurality of APs in the 3-D space and the interference from the neighboring AP.

An intelligent wireless broadband network and content delivery management within a network includes at least one datacenter, at least one network tower and a plurality of smart nodes may be provided. Each of the plurality of smart nodes may be deployed as a micro point of presence (micro POP) at the at least one datacenter the at least one tower and at each of a plurality of hub-homes within the network. An artificial intelligence (AI) capable compute unit may be configured to provide customization of the plurality of smart nodes based on usage pattern of the plurality of homes at a neighborhood level, and thereby facilitating a dynamic edge network distribution solution for better Internet experience to the end-users.

Custom-tailored warranties are provided with improved service level agreements (SLA) based upon an estimated turnaround time for service and/or parts. The turnaround time is calculated using an artificial intelligence or machine learning engine considering parameters such as the transit time from the nearest service centers and warehouses, the availability of service engineers at the service centers, and the availability of replacement parts in the warehouse. A custom-tailored warranty also may be offered for a specific customer-selected SLA if supported by the estimated turnaround time for the location. A warranty recommendation may be based on device location for data centers in multiple locations. A Location-Based Warranty Monitor (LBWM) provides fine-grained warranty suggestions and Un-bound Warranty Tokens (UWTs) can be bound to a system to assign a warranty with a desired. SLA.

This application provides a method for dynamically switching antennas. User equipment determines an antenna switching sequence based on a networking mode of the user equipment and an actual scenario, and performs antenna switching based on the determined antenna switching sequence. When the technical solutions of this application are implemented, a problem that a conflict exists in an antenna switching process is effectively resolved without adding hardware.

Systems and methods of determining a reporting configuration associated with a coverage level of a wireless device are provided. In one exemplary embodiment, a method performed by a wireless device (105, 200, 300, 400, 1000) in a wireless communication system (100) includes obtaining (503) information indicating a coverage level (113a-d) of the wireless device. Further, the method includes determining (507), from amongst different reporting configurations (115a-d) respectively associated with different coverage levels of the wireless device, the reporting configuration associated with the coverage level indicated by the obtained information. Also, the method includes reporting (511) a measurement result using the determined reporting configuration.

Systems and methods of determining a reporting configuration associated with a coverage level of a wireless device are provided. In one exemplary embodiment, a method performed by a wireless device (105, 200, 300, 400, 1000) in a wireless communication system (100) includes obtaining (503) information indicating a coverage level (113a-d) of the wireless device. Further, the method includes determining (507), from amongst different reporting configurations (115a-d) respectively associated with different coverage levels of the wireless device, the reporting configuration associated with the coverage level indicated by the obtained information. Also, the method includes reporting (511) a measurement result using the determined reporting configuration.

Methods and apparatus for determining losses due to obstructions in a wireless communications system are described. Pairs of measurements points, one of each side of an obstruction are selected, and wireless device reported received signal energy measurements corresponding to the pair of selected locations are used to determine a path loss through the obstruction. In some embodiments, the pair of measurements points are selected based on one or more of: wireless device orientation at the time of measurement, application in use at the time of measurement, time between measurements, or location between measurements. In one example, a first selected location in the pair corresponds to an outdoor location with a unobstructed line of sight view to the base station, while the second selected location corresponds to an indoor location.

Methods and apparatus for determining losses due to obstructions in a wireless communications system are described. Pairs of measurements points, one of each side of an obstruction are selected, and wireless device reported received signal energy measurements corresponding to the pair of selected locations are used to determine a path loss through the obstruction. In some embodiments, the pair of measurements points are selected based on one or more of: wireless device orientation at the time of measurement, application in use at the time of measurement, time between measurements, or location between measurements. In one example, a first selected location in the pair corresponds to an outdoor location with a unobstructed line of sight view to the base station, while the second selected location corresponds to an indoor location.