The invention relates to the field of wireless mesh communication networks and in particular to methods, networks and nodes (101) for use in such a wireless mesh network (100) for establishing routes in the wireless mesh network (100) by pro-actively regularly sending many-to-one route requests at randomized intervals by wireless network nodes (101) that can operate as a proxy nodes for a mobile wireless device (104) communicating using a first wireless communication protocol and further nodes (102, 103) in the wireless mesh network (100) communicating using a second wireless communication protocol.

The invention relates to the field of Zigbee wireless mesh communication networks and in particular to methods, systems and nodes (A,B,C,D) for use is such systems for establishing routes in mesh networks, wherein Zigbee router nodes (A,B,C) comprise a controller and radio transceiver and are arranged to include addresses of Zigbee End Device, ZED, child nodes (D) of the Zigbee router (C), in many-to-one route requests that the Zigbee router (C) transmits and/or include the addresses of the ZED child nodes (D) of the Zigbee router (C) in AODV route replies that the Zigbee router (C) transmits.

The invention relates to the field of Zigbee wireless mesh communication networks and in particular to methods, systems and nodes (A,B,C,D) for use is such systems for establishing routes in mesh networks, wherein Zigbee router nodes (A,B,C) comprise a controller and radio transceiver and are arranged to include addresses of Zigbee End Device, ZED, child nodes (D) of the Zigbee router (C), in many-to-one route requests that the Zigbee router (C) transmits and/or include the addresses of the ZED child nodes (D) of the Zigbee router (C) in AODV route replies that the Zigbee router (C) transmits.

An apparatus, system, method, and computer-readable recording media perform smart control in a wireless network, which includes a plurality of wireless devices. Configuration parameters are obtained to set one wireless device as an active master device in the wireless network. The active master device receives updates in the configuration parameters and learned station (STA) information, and periodically transmits the updates to the configuration parameters and the learned STA information to the other wireless devices in the wireless network. Any one of the other wireless devices in the wireless network can use the updates to the configuration parameters and the learned STA information to be set as a new active master device in the wireless network when the active master device becomes out of network.

A data transmission method and a first electronic device are provided. The data transmission method includes: sending a first request to a second electronic device in a case that a first electronic device accesses a network hotspot of the second electronic device; receiving a first response of the network hotspot that is fed back by the second electronic device in response to the first request. The first response includes the hotspot information. The data transmission method further includes when the hotspot information does not include a Domain Name Service (DNS) parameter of the network hotspot, configuring a data network route to transmit first data, and configuring a target policy route to transmit second data. The second data is data transmitted between the first electronic device and the network hotspot.

A user equipment (UE) may communicate using different radio access technologies on adjacent frequency bands. The UE may determine that the UE is not receiving wireless signals for a second radio access technology that utilizes a second frequency band adjacent to a first frequency band for a first radio access technology. The UE may place a transmitter of the UE in a filter bypass mode in which a transmit signal bypasses a transmit filter for the first radio access technology in response to determining that the wireless signals for the second radio access technology are not received. The UE may scan, using a receiver for the second radio access technology, while in the filter bypass mode, the second frequency band for a signal for the second radio access technology between scheduled transmissions for the first radio access technology.

An operation method of a first terminal in a communication system may comprise: receiving a link establishment request message from a second terminal; transmitting, to the second terminal, a link establishment response message including a node address of a first base station in response to the link establishment request message; and receiving a link establishment completion message from the second terminal.

An operation method of a first terminal in a communication system may comprise: receiving a link establishment request message from a second terminal; transmitting, to the second terminal, a link establishment response message including a node address of a first base station in response to the link establishment request message; and receiving a link establishment completion message from the second terminal.

To provide a low latency near RT RIC, some embodiments separate the RIC's functions into several different components that operate on different machines (e.g., execute on VMs or Pods) operating on the same host computer or different host computers. Some embodiments also provide high speed interfaces between these machines. Some or all of these interfaces operate in non-blocking, lockless manner in order to ensure that critical near RT RIC operations (e.g., datapath processes) are not delayed due to multiple requests causing one or more components to stall. In addition, each of these RIC components also has an internal architecture that is designed to operate in a non-blocking manner so that no one process of a component can block the operation of another process of the component. All of these low latency features allow the near RT RIC to serve as a high speed IO between the E2 nodes and the xApps.

Aspects of the disclosure relate to control of discovery signal transmissions for D2D communication. A first UE may transmit a discovery signal initiation message to at least a second UE to control transmission of a discovery signal from the second UE to a third UE. The second UE may identify a discovery signal monitoring duration of the second UE during which the second UE monitors for transmitted discovery signals transmitted from other UEs to the third UE. At expiration of the discovery signal monitoring duration, the second UE may transmit a discovery signal to the third UE when the number of transmitted discovery signals transmitted from the other UEs during the discovery signal monitoring duration is less than a discovery signal transmission number threshold.