A network function selectively supports a mobile device with network settings appropriate for the device context of the mobile device. The network function obtains a device profile for the mobile device, which identifies multiple device groups, with each device group being associated with a corresponding set of network settings. The network function selects a device group among the device groups in the device profile based on the device context of the mobile device. The network function directs at least one network function in the network to support the mobile device with a set of network settings corresponding to the selected device group.

Example communication methods and apparatus are described. One example communication method includes receiving first indication information by a first network element from a second network element, where the first indication information is used to indicate that a current condition supports establishment of a session of a first network for a terminal apparatus. The first network element obtains first quality of service (QoS) control information of a first session of the terminal apparatus after receiving the first indication information, where the first session is a session established by the terminal apparatus by using a second network. The first network element sends the first QoS control information to the second network element.

Example communication methods and apparatus are described. One example communication method includes receiving first indication information by a first network element from a second network element, where the first indication information is used to indicate that a current condition supports establishment of a session of a first network for a terminal apparatus. The first network element obtains first quality of service (QoS) control information of a first session of the terminal apparatus after receiving the first indication information, where the first session is a session established by the terminal apparatus by using a second network. The first network element sends the first QoS control information to the second network element.

A wireless communication method, a terminal device, and a network device. The method comprises: a terminal device receives a first message sent by a first network device, the first message being used for determining a change in quality of service (QoS) related information; the terminal device determines, according to first condition information, a condition for changing the QoS related information.

A wireless communication method, a terminal device, and a network device. The method comprises: a terminal device receives a first message sent by a first network device, the first message being used for determining a change in quality of service (QoS) related information; the terminal device determines, according to first condition information, a condition for changing the QoS related information.

Aspects of the disclosure relate to positioning, navigation, and timing (PNT) satellite beam and data scheduling. In one or more embodiments, a method for determining a location and/or time offset of at least one receiver involves transmitting, by at least one satellite, at least one beam, which is a sweeping beam. In one or more embodiments, each of the beams comprises at least one signal used for positioning, navigation, or timing. The method further comprises varying, by at least one satellite, aspects of at least one signal based on optimization parameters. In at least one embodiment, the optimization parameters comprise a location of a beam footprint of at least one beam. In one or more embodiments, at least one receiver receives at least one signal. In at least one embodiment, the location and/or the time offset of at least one receiver is determined by using at least one signal.

Aspects of the disclosure relate to positioning, navigation, and timing (PNT) satellite beam and data scheduling. In one or more embodiments, a method for determining a location and/or time offset of at least one receiver involves transmitting, by at least one satellite, at least one beam, which is a sweeping beam. In one or more embodiments, each of the beams comprises at least one signal used for positioning, navigation, or timing. The method further comprises varying, by at least one satellite, aspects of at least one signal based on optimization parameters. In at least one embodiment, the optimization parameters comprise a location of a beam footprint of at least one beam. In one or more embodiments, at least one receiver receives at least one signal. In at least one embodiment, the location and/or the time offset of at least one receiver is determined by using at least one signal.

A method and system for maintaining service continuity of a roaming user across multiple networks is disclosed. The method includes receiving a request for handover of the roaming user from a source network to a target network. The method includes assessing a capability of the target network to accommodate the roaming user arriving from the source network. The method includes performing a Service Level Agreement (SLA) fulfilment negotiation by the target network with the source network. The method further includes configuring the target network to facilitate the handover of the roaming user from the source network to the target network. The method includes transferring the roaming user from the source network to the target network along with the plurality of services. The method includes monitoring efficacy of the service continuity for the transferred roaming user after movement of the roaming user from the source network to the target network.

A method and system for maintaining service continuity of a roaming user across multiple networks is disclosed. The method includes receiving a request for handover of the roaming user from a source network to a target network. The method includes assessing a capability of the target network to accommodate the roaming user arriving from the source network. The method includes performing a Service Level Agreement (SLA) fulfilment negotiation by the target network with the source network. The method further includes configuring the target network to facilitate the handover of the roaming user from the source network to the target network. The method includes transferring the roaming user from the source network to the target network along with the plurality of services. The method includes monitoring efficacy of the service continuity for the transferred roaming user after movement of the roaming user from the source network to the target network.

Methods, media, and systems are provided for a priority-based multi-user (MU) multiple-input multiple-output (MIMO) pairing threshold for codebook beamforming. The methods, media, and systems identify a plurality of user device candidates for a user device pairing. A first user device of the plurality of user device candidates having a higher priority than another user device of the plurality of user device candidates is identified. A correlation of the first user device with a second user device of the plurality of user device candidates is determined to be below a threshold. Based on determining that the correlation is below the threshold, the first user device is paired with the second user device for sharing a resource.