Embodiments are presented for collaborative device address generation between a wireless client device and a network infrastructure component, such as a wireless access point. The wireless client device and network infrastructure component share information to facilitate collaborative generation of a sequence of device addresses. This shared information includes, in some embodiments, key information and moving factor information. The key information and moving factor information is used to generate a token. A sequence of tokens is generated by updating the moving factor as each token is generated. A corresponding sequence of device addresses are then derived based on the sequence of tokens. Since the wireless client device and the network infrastructure device apply equivalent methods to generate respective sequences of addresses, the network infrastructure is able to efficiently identify a source wireless client device when observing a new device address on a wireless network.

A transceiver of a mobile device may receive a beacon transmitted by a mesh network member mobile device. A processor of the mobile device may extract a crew ID from the beacon. The processor may determine that the crew ID matches a crew ID of a user logged into the mobile device. In response to determining that the crew ID matches the crew ID of the user, the processor may generate a reply beacon. The transceiver may transmit the reply beacon. The transceiver may receive a response to the reply beacon. The response may include a job ID enabling the user to clock into a job. The processor may clock the user into the job. As a result of clocking the user into the job, the mobile device may become a member of the mesh network.

Aspects of the subject disclosure may include, for example, identifying an assigned friendly-phrase embedded universal integrated circuit card identifier (fpEID) for a wireless communication device and sending a service request message to a service provider network to initiate a service activation procedure, the service request message comprising the assigned fpEID. Various embodiments can include sending an fpEID assignment request message to a device vendor network, receiving an fpEID assignment confirmation message from the device vendor network in response to the fpEID assignment request message, and identifying the assigned fpEID based on the fpEID assignment confirmation message. Other embodiments are disclosed.

A method for initializing an electronic subscriber identity module (SIM) is provided. The method includes selecting a first bootstrap profile out of a plurality of bootstrap profiles configured with a device, wherein the first bootstrap profile is set with a first range of international mobile subscriber identifiers (IMSIs); activating the first bootstrap profile; attempting to connect to a first cellular network through an IMSI in the range of IMSIs; and establishing a connection with a central server when the device is connected to the first cellular network. The method may be operated by any device configured to connected to a cellular network.

Embodiments are presented for collaborative device address generation between a wireless client device and a network infrastructure component, such as a wireless access point. The wireless client device and network infrastructure component share information to facilitate collaborative generation of a sequence of device addresses. This shared information includes, in some embodiments, key information and moving factor information. The key information and moving factor information is used to generate a token. A sequence of tokens is generated by updating the moving factor as each token is generated. A corresponding sequence of device addresses are then derived based on the sequence of tokens. Since the wireless client device and the network infrastructure device apply equivalent methods to generate respective sequences of addresses, the network infrastructure is able to efficiently identify a source wireless client device when observing a new device address on a wireless network.

This application describes a phased approach to provision eSIM profiles to a wireless device. Credentials are preloaded to an eUICC during manufacture of the eUICC and used subsequently to load eSIM profiles to the eUICC without requiring an active, real-time connection to an MNO provisioning server. Multiple bound profile packages (BPPs) can be pre-generated and encrypted by MNO provisioning servers for an eUICC and transferred to a BPP aggregator server before assembly of the eUICC in a respective wireless device. A local provisioning server in a manufacturing facility mutually authenticates and connects to the BPP aggregator server to download and store one or more of the encrypted BPPs for later installation on the eUICC. The local provisioning server subsequently mutually authenticates and connects to the eUICC to load at least one of the one or more pre-generated, encrypted BPPs to the eUICC during assembly and/or testing of the wireless device.

A Fixed Wireless Access (FWA) device can include identification information disposed on an exterior surface of the FWA device. The FWA device can be configured to receive over a local communication network from a mobile device, provisioning information associated with the FWA device based on the identification information and install the provisioning information in a memory unit. The FWA device can establish cellular connectivity with a network base station based on the provisioning information. The provisioning information can be obtained by the mobile device scanning the identification information, providing the identification information to a server, and receiving the provisioning information from the server based on the identification information.

A terminal for performing an onboarding procedure for remote provisioning through steps of: receiving an onboarding enabled indication from at least one onboarding network; selecting an onboarding network based on the onboarding enabled indication and onboarding network selection information; and attempting registration for the selected onboarding network is provided.

A system is configured to provide managed services for deployment of shared tangible objects by an operator. The system includes cloud resources provided by the system administrator. In one embodiment, the cloud resources include a sharable-object command module configured to communicate signals employed in activating shared tangible objects for use when the end user is successfully authorized by the device activation module. The system includes an API provided by the system administrator. The API is configured to facilitate a communication of object activation signals from the sharable-object command module to allow the end user to use the shared tangible object. The same API is employed to facilitate the communication of object activation signals for different types of shared tangible objects that can be provided in different vertical markets.

The present application relates to devices and components including apparatus, systems, and methods for paging timing collision control, with respect to exchange of offset values (e.g., IMSI offset values) between a user equipment and a network.