Method and apparatus for monitoring the status and location of personnel using a remote timer. In some embodiments, a method includes logging in, through a network accessible device, a geo position of a subject to initiate a monitored session associated with the subject. A countdown timer of a remote server is initiated to denote a monitored time interval, the remote server in communication with the network accessible device over a network. A notification is generated and transmitted across the network to a monitoring device responsive to a conclusion of the monitored time interval.

A method performed in a user equipment, UE, (1) and a gateway (2) for data communication in a 3GPP network via an access point name, APN, capable of providing support for packet data network, PDN, connectivity using a first internet protocol version and PDN connectivity using a second internet protocol version. The method comprises the steps of the UE requesting (S1) dual stack PDN connectivity from a gateway (2) and receiving (S2) a single IP address on either the first or the second internet protocol version from the gateway (2) and further receiving (S3) from the gateway (2) a cause code indicating that only the assigned PDN and internet protocol version is allowed.

Systems and methods are provided for efficient communication through a fabric network of devices in a home environment or similar environment. For example, an electronic device may efficiently control communication to balance power and reliability concerns, may efficiently communicate messages to certain preferred networks by analyzing Internet Protocol version 6 (IPv6) packet headers that use an Extended Unique Local Address (EULA), may efficiently communicate software updates and status reports throughout a fabric network, and/or may easily and efficiently join a fabric network.

A wireless communication terminal for wireless communication is disclosed. The wireless communication terminal includes: a transceiver; and a processor. The processor is configured to transmit a non-legacy physical layer frame including a legacy signaling field including information decodable by a legacy wireless communication terminal by using the transceiver.

System and methods for efficient user plane function (UPF) selection are described. A mobile device (UE) may transmit a connection request to a 5G core network. The connection request can include an indication that the type of data to be serviced is IPv4-type traffic. The access management function (AMF) receives the request from a base station (e.g., gNodeB) and queries a network function repository function (NRF) for an identification of a session management function (SMF). The selected SMF queries a session management function datastore. If the SMF selected by the NRF is capable of IPV4 traffic, the identification of the SMF is returned to the AMF. If the SMF is not capable of IPV4 traffic, the identification of a capable SMF using the information received in the SMF status datastore is returned to the AMF through a 308 code. The mobile device is thereafter connected to the capable UPF.

A sensor platform includes a programmable microcontroller to execute programming associated with one or more sensors in order to receive data from the one or more sensors and generate reports based on the data, and to enter a power-down mode in the absence of the data. The sensor platform also includes first and second transceivers. The first transceiver is configured to establish wireless connectivity with user devices using a first wireless protocol and to receive the programming from one or more of the user devices using the first wireless protocol. The second transceiver is configured to transmit the reports to a gateway using a second wireless protocol that is lower power, longer range, and/or lower fidelity than the first wireless protocol.

A device can receive, from a network device, a request to create an internet protocol (IP) session for a user device. The device can allocate an IP address for the user device and a first tunnel endpoint identifier associated with a tunnel. The IP address can include a first set of bits associated with a location identifier and a second set of bits associated with a device identifier. The device can provide a response to the network device, and can receive a request that includes a second tunnel endpoint identifier associated with the tunnel. The device can provide the IP address and the first and second tunnel endpoint identifiers to be stored using a data structure. The device can provide a response to the network device indicating to establish the downlink portion of the IP session, and can perform one or more actions associated with managing the IP session.

The present document describes a dynamic mobility management system. The disclosure describes a mobility management mechanism that is able to maintain the IP address assigned when a session was initiated in the user device to exchange data packets between the end-points of a given data service. This is possible through the management of the distributed mobility anchors, tunnels, interfaces and IP addresses, where a mobile node is configured to bind to the previously accessed mobility access router, such that the previously established network sessions of the mobile node are re-established through said previously accessed mobility access router. The disclosure is applied in the Information and Communication Technology domain, more precisely in the mobility management in communication networks.

Systems and methods for the management of communications related to telecommunications-based devices are provided. Telecommunications-based devices initiate requests to gateway computing devices corresponding to a radio communication network to establish data communications. The gateway computing device accepts the communication request and specifies an ordered preference of one or more communication protocols that will be used telecommunications-based devices accessing the wireless communication network. The telecommunications-based device processes the acceptance and selects a communication protocol from the ordered preference provided by the gateway computing device.

A first field of a preamble of a physical layer (PHY) data unit is generated to include a first set of one or more information bits indicating a duration of the data unit and is formatted to conform to a first communication protocol such that the first field allows a receiver device conforming to a second communication protocol to determine the duration of the data unit. A second field of the preamble is generated to include a second set of one or more information bits indicating to a receiver device conforming to the first communication protocol that the data unit conforms to the first communication protocol. The second field is convolutionally coded using a tail biting technique, and the first field and the second field are modulated using a modulation scheme specified for a field corresponding to the first field and the second field, respectively, by the second communication protocol.