Enterprise and consumer billing allocation for wireless communication device service usage activities is provided. In some embodiments, enterprise and consumer billing allocation for wireless communication device service usage activities includes monitoring a service usage activity of a wireless communication device, and determining an enterprise and consumer billing allocation for the monitored service usage activity. In some embodiments, enterprise and consumer billing allocation for wireless communication device service usage activities includes monitoring a service usage activity of a wireless communication device, and reporting the monitored service usage activity to a network element, in which the network element determines an enterprise and consumer billing allocation for the monitored service usage activity. In some embodiments, enterprise and consumer billing allocation for wireless communication device service usage activities includes providing a service design center for configuring an enterprise and consumer billing allocation of monitored service usage activities for a plurality of wireless communication devices associated with an enterprise account, and implementing the configured enterprise and consumer billing allocation for monitored service usage activities for the plurality of wireless communication devices associated with the enterprise account.

A system for handling calls in a network includes a memory storing instructions and a processor configured to execute the instructions to perform operations. The operations include receiving information about the calls for a time interval, determining, for the time interval, a total cost associated with handling the calls, including a network cost associated with transmitting data over the network, a processing cost for processing the information related to the calls, and a cost of dynamically reassigning master and slave roles to a plurality of nodes in the network. The operations further include determining an assignment of the master and slave roles for a plurality of accounts being handled by the plurality of nodes that results in the total cost having a minimum value, and implementing the optimal assignment among the plurality of the accounts based on the determination.

Aspects of the subject disclosure may include, for example, a network device that comprises a processing system including a processor and a memory storing instructions that, when executed by the processing system, facilitate performance of operations. The operations include obtaining timing advance data regarding a communication device served by the network; the timing advance data is collected by a network element coupled to the network device, and the network element communicates with the communication device using control-plane signaling. The timing advance data is processed using location data regarding the network element to determine a geolocation of the communication device. The geolocation is stored at a storage device; the network device and storage device are included in a secure portion of the network. The geolocation is provided to equipment of a network customer accessing the secure portion of the network via a secure interface. Other embodiments are disclosed.

The present invention discloses methods and systems for communicating at a cellular router between a first wireless communication module and a first subscriber identity module (SIM). The cellular router receives a first request from a first wireless communication module and encapsulates the first request in a first modified request. The cellular router then sends the first modified request to a first SIM card in a first communication apparatus and waits for a first modified reply. While waiting for the first modified reply the cellular router sends at least one halt message to the first wireless communication module after a first time threshold. After receiving the first modified reply, the cellular router decapsulates the first modified reply to retrieve a first reply and sends the first reply to the first wireless communication module where the first modified reply is a reply to the first.

Disclosed here is a method to determine a user intent when a user device initiates an interactive voice response (IVR) call with a wireless telecommunication network. A processor can detect the IVR call initiated with the network and determine whether the user device is a member of the network. Upon determining that the user device is a member of the network, the processor can obtain user history including interaction history between the user and the network. Based on the user history, the processor can predict the user intent when the user initiates the IVR call. The processor can detect whether user device is a 5G capable device. Upon the determining that the device is 5G capable and based on the predicted user intent, the processor can suggest to the user an application configured to execute on the user device and configured to address the predicted user intent.

The invention relates to a human mobility measuring method comprising a structuring step where CDR raw metadata is filtered so as to identify a device identification, a cell site identification, a date, and a time; a data frame generating and sorting step where the filtered CDR metadata is sorted and the filtered sorted CDR metadata are projected into an occupancy grid comprising a location vs. time-bin matrix, a probabilistic map generating step of a device's location in space and time, and a filtering step to accurately represent human mobility from patterns that reflect errors, uncertainties, or patterns not related with real human mobility. The method further comprises a gap filling process allowing for a continuous localization of the device by extrapolating any trajectory in space and time of any device and a projecting step comprising projecting the trajectories defined at a Voronoi grid defined by the sites and towers to the road and street grid

There is disclosed in one example a computing apparatus, including: a hardware platform including a processor and a memory; a transceiver; a local user display; and instructions encoded within the memory to instruct the processor to: locate via the transceiver at least one nearby device; receive observational profile information for the nearby device; and display on the local user display information about the nearby device's observation abilities.

The invention provides a method and system for sharing Wi-Fi in a Wi-Fi network using a cloud platform. To start with, the method and system enables registration of one or more Wi-Fi access points on the cloud platform and enables a client device to rent a Wi-Fi connection from owner of a Wi-Fi access point. Subsequently, the method and system enables the client device to select a Wi-Fi access point registered on the cloud platform based on usage fee, properties and signal quality. Further, the method and system performs offload optimization using an AI module by deciding whether data offloading from licensed spectrum to unlicensed spectrum is desirable or not. In response to deciding that data offload is desirable, the client device is allowed to connect to the selected Wi-Fi access point and transact with the Wi-Fi access point owner using cryptocurrencies in a blockchain-based network.

Aspects of the present disclosure relate to systems and methods for a wireless communication tag. The tag is configured to uniquely identify an account associated with the user for granting the user access to a first access-controlled service controlled by a first authority and a second access-controlled service controlled by a second authority. The tag is implemented through an omnidirectional antenna removably coupled to a mobile device associated with the user. An amount of payment owed by the user in accessing the first access-controlled service from a plurality of access-controlled services including the first access-controlled service and the second access-controlled service across a plurality of authorities is determined and transfer of the amount of payment to the first authority selected from the plurality of authorities in response to the user accessing the first access-controlled service is facilitated.

An infrastructure-controller (206) for an infrastructure (202), wherein the infrastructure has a plurality of Bluetooth Low Energy, “BLE”, nodes (208, 210, 212) associated with it. The infrastructure-controller (206) is configured to: identify one of the plurality of BLE nodes as a current-BLE-node (212), and activate the current-BLE-node (212) for communication with a key (204) using BLE signals; determine a communication-quality-indicator for each of the plurality of BLE nodes (208, 210, 212), that represents the quality of communication with the key (204); based on the communication-quality-indicators, identify one of the plurality of BLE nodes as a next-BLE-node (210); and provide connection-information to the next-BLE-node (210) using out-of-band signalling (214). The infrastructure-controller (206) can then deactivate the current-BLE-node (212); and activate the next-BLE-node (212) for continued communication with the key (204) using BLE signals.