Facilitating unified mobility management for metaverse and physical worlds in advanced networks is provided herein. Operations of a system include determining a change has occurred to a service parameter of a user equipment executing a metaverse experience. The metaverse experience can include a combination of first usage of a first resource selected from a first group of resources associated with a physical world and second usage of a second resource selected from a second group of resources associated with a virtual world. The operations can also include executing a mobility management microservice for the user equipment, wherein the mobility management microservice is selected based on a type of the change to the service parameter.

Various enhanced operational and communication handling techniques for satellite devices are discussed herein. In one example, a method of operating an orbital satellite device of a satellite cluster is provided. The method includes identifying operational status information for at least a peer satellite device in communication range of the satellite device. Based at least on the operational status information, the method includes selecting a quality of service level for communications to be transferred to the peer satellite device, and applying the quality service level to transmit data packets to the peer satellite device.

A method of supporting communication using two or more heterogeneous radio access technologies (RAT) may include receiving, from a first communication network supporting a first RAT, a first message requesting notification as to whether access to a second communication network that simultaneously support the first communication network and a second RAT is supported; transmitting, to the base station in the first communication network, a second message including an indicator indicating whether to support simultaneous access to the first and second communication networks in response to the first message; and receiving a trigger condition for reporting a measurement result for the second communication network from the base station in the first communication network, when the indicator indicates that the terminal is able to access the first and second communication networks.

Systems and methods are disclosed for a decentralized electronic subscriber identity module (dSIM) and an intelligent multi-chain offloading platform to leverage a plurality of decentralized blockchain-based cellular networks. In one embodiment, an AI-enabled offloading gateway can interconnect a plurality of mobile network operators with said decentralized blockchain-based cellular networks using a dSIM profile. The dSIM profile may contain symmetric and/or asymmetric network access applications, Proof-of-Coverage, and Quality-of-Service applications. The offloading gateway may include of various server nodes exposing network access and blockchain interfaces to mobile operators' systems and subscriber equipment containing dSIM profiles inside embedded or integrated universal integrated circuit cards (eUICCs/iUICCs).

Disclosed are a channel switching method, an electronic device, and a storage medium. The electronic device includes a first network channel and a second network channel. The method includes: starting a first application, where the first application includes a first data flow and a second data flow, and the first data flow and the second data flow are carried on the first network channel; and switching the network channel carrying the first data flow and the second data flow to the second network channel in a case of detecting that network quality of the first data flow does not meet a preset condition. This application can better resolve the lag in service operation, thereby improving user experience.

Techniques to incorporate quality of experience (QoE) in mobility management are disclosed. A user equipment (UE) may provide a QoE report to network (e.g., cell) upon detection of a QoE report triggering event (e.g., mobility management, environmental trigger, etc.). The QoE report may comprise information related to QoE metrics such as uplink (UL) latency, UL throughput, UL error rate, downlink (DL) frequency, DL throughput, DL error rate, handover (HO) frequency, beam switch frequency, UE power consumption, etc. The network may take actions such as sending a mobility management command if it is decided that QoE should be restored to the UE.

Configurations are described for maintaining a continuity and quality of wireless signal connection between a mobile device and systems accessible through the internet. In particular, configurations are disclosed to address the challenge of a mobile device that moves through a physical environment wherein the best wireless connectivity performance is achieved by switching between available connection sources and constantly evaluating a primary connection with other available connections that may be switched in to become a new primary connection. The mobile device may be self-propelled or carried by some other mobilizing means.

Configurations are described for maintaining a continuity and quality of wireless signal connection between a mobile device and systems accessible through the internet. In particular, configurations are disclosed to address the challenge of a mobile device that moves through a physical environment wherein the best wireless connectivity performance is achieved by switching between available connection sources and constantly evaluating a primary connection with other available connections that may be switched in to become a new primary connection. The mobile device may be self-propelled or carried by some other mobilizing means.

The present disclosure discloses a method and a device used for power adjustment in a User Equipment (UE) and a base station. The UE receives L reference signal groups transmitted by L antenna port sets respectively; receives R first signaling(s) for determining R first offset(s); and then transmits a first radio signal for determining K difference value(s) corresponding to K first reference power value(s) respectively, each of which is linearly correlated to a sum of the R first offset(s). Measurement(s) on K reference signal group(s) is (are) respectively used for determining K first reference power value(s). A transmitting power of the first radio signal is a first power associated with a first reference signal group, which is one of the K reference signal group(s). All of the L antenna port sets are used for one same serving cell or carrier. The disclosure helps improve power control performance and reduce overhead.

A method for a handover of a mobile station performed by a source base station and a target base station. The target base station receives a handover request message, from the source base station, in which includes QoS information of the mobile device, radio bearer identifier information of the source base station, and a first mapping relationship between a flow and a radio bearer of the source base station, the target base station acknowledges with a handover acknowledgement message. Therefore resource preparation at the target base station during a handover procedure is improved.