During operation, a mesh network access point (MAP) may communicate, via multiple mesh paths in a mesh network with the one or more root access points (RAPs), uplink packets or frames to or from at least two electronic devices. Notably, at a given time, the MAP uses a first mesh path in the mesh paths to communicate a first subset of the uplink packets or frames associated with a first electronic device in the two electronic devices and uses a second (different) mesh path in the mesh paths to communicate a second subset of the uplink packets or frames associated with a second electronic device in the two electronic devices. Moreover, the MAP may dynamically distribute the first electronic device or the second electronic device over the multiple mesh paths, e.g., based at least in part on one or more communication-performance metrics of the mesh paths and/or the mesh network.

In example implementations, methods for selecting a network connection for paired endpoint devices and an apparatus for performing the same is provided. The method includes establishing a connection to a mobile endpoint device. A first quality score associated with a wireless connection of the mobile endpoint device is calculated based on a parameter associated with the wireless connection between the mobile endpoint device and a wireless network. A network selection is made based on a comparison of the first quality score and a second quality score. The second quality score is associated with a connection between the computer and a communication network.

A communication device mounted on a vehicle and an operation method of the communication device are provided. The communication device performs a connection with a communication terminal included in a vehicle stopped or driving in a vicinity of the vehicle via device-to-device communication, provide subscriber identity module (SIM) information to the connected communication terminal, request execution of a communication relay function from the communication terminal, and in response to a communication relay function acceptance signal being received from the communication terminal, transmit and receive data to and from the base station by using the communication terminal as a communication relay.

Methods, systems, and devices for wireless communications are described. A user equipment (UE) may monitor one or more first conditions pertaining to non-cellular communications between the UE and a non-cellular network while the UE is operating in a dual networking mode for steering, switching, or splitting traffic (e.g., an access traffic steering, switching, and splitting (ATSSS) mode) between the non-cellular network and a cellular network. The UE may predict an availability status of at least the non-cellular network based on at least one of the one or more first conditions. In some cases, the UE may determine whether to change dual networking modes based on the availability status and may communicate in accordance with the same or a different dual networking mode using at least one of the cellular network, the non-cellular network, or a combination thereof based on the prediction.

Redundant upstream mesh links are formed with a gateway access point for each of the radio capabilities. A resource load is measured across each of the redundant upstream mesh links. During runtime, a packet is received for upstream (or downstream) transmission from a specific client from the plurality of clients. An upstream link is selected for transmission of the packet from the redundant upstream mesh links for transmission of the packet and packets of the packet session, based on a highest link quality available from the plurality of mesh links according to the resource load measurement.

Various aspects of the present disclosure generally relate to wireless communication. In some aspects, a network node may receive an indication of a first set of parameters that corresponds to a direct communication link between an industrial internet-of-things (IIoT) device and a first controller; receive an indication of a second set of parameters that corresponds to an indirect communication link between the IIoT device and the first controller through a second controller; and schedule a communication on at least one of the direct communication link or the indirect communication link based at least in part on the first set of parameters and the second set of parameters. Numerous other aspects are provided.

Various aspects of the present disclosure generally relate to wireless communication. In some aspects, a network node may receive an indication of a first set of parameters that corresponds to a direct communication link between an industrial internet-of-things (IIoT) device and a first controller; receive an indication of a second set of parameters that corresponds to an indirect communication link between the IIoT device and the first controller through a second controller; and schedule a communication on at least one of the direct communication link or the indirect communication link based at least in part on the first set of parameters and the second set of parameters. Numerous other aspects are provided.

A data transmission method, electronic device and computer readable storage medium are provided. The method includes: acquiring a first data packet to be sent; determining a first data stream to which the first data packet belongs; detecting a link state of the first data stream; when the link state of the first data stream is an establishing state, and the first data packet is sent for the first time, selecting a first wireless communication link from the plurality of wireless communication links for the first data packet, and marking the first data packet according to a first link identifier of the first wireless communication link; and sending the first data packet through a network interface of the first wireless communication link according to the first link identifier.

A data transmission method, electronic device and computer readable storage medium are provided. The method includes: acquiring a first data packet to be sent; determining a first data stream to which the first data packet belongs; detecting a link state of the first data stream; when the link state of the first data stream is an establishing state, and the first data packet is sent for the first time, selecting a first wireless communication link from the plurality of wireless communication links for the first data packet, and marking the first data packet according to a first link identifier of the first wireless communication link; and sending the first data packet through a network interface of the first wireless communication link according to the first link identifier.

Techniques, devices, and systems for implementing a Priority Data Transport Service (PDTS) are disclosed. The PDTS provides authorized devices and/or authorized users with on-demand, priority data transport (e.g., priority Internet access). For example, the PDTS allows authorized devices and/or authorized users to access the Internet, use mobile applications, and/or send and receive image data, video data, and text data in a prioritized manner, as compared to the regular (non-priority) Internet access that is provided to non-subscribers of the PDTS over commercial telecommunications networks. An authorized user may activate and deactivate the PDTS on demand. For instance, the PDTS may be activated during an emergency or crisis situation when networks may be congested, thereby providing the user with priority data transport (e.g., priority Internet access) in an emergency or crisis situation when a telecommunications network may be overloaded.