An abnormal traffic analysis apparatus includes receiving means for receiving traffic from a device, analysis means for analyzing whether or not traffic received from the device is abnormal traffic, analysis result recording means for recording a result of analysis performed by the analysis means, and device management means for managing movement of the device between edges. If it is determined by the device management means that a device that is a target of analysis performed by the analysis means moves to an edge, the receiving means creates information for continuing analysis of traffic received from the device and transmits the information to an apparatus for analyzing traffic that is included in the edge to which the device moves.

A group of wireless devices may use shared resources to communicate information to a base station. At least one configuration parameter (e.g., QoS parameter(s)) associated with over-the-air computation may be used for group uplink transmissions. Data associated with the group of wireless devices may be determined, based on an aggregation of the group uplink transmissions, and/or may be provided to a network node using the configuration parameter(s).

This application provides a data processing method and device, to implement bearer mapping of control plane signaling of user equipment on each interface. An IAB system includes a centralized unit CU, a distributed unit DU, a first IAB node, and a second IAB node. The method includes: generating, by the CU, a downlink F1AP message, where a message included in the downlink F1AP message is one or a combination of the following: an F1AP message of a terminal device, an F1AP message of the first IAB node, and an RRC message of the second IAB node; and sending, by the CU, the downlink F1AP message to the DU, and indicating that a message type of the message included in the downlink F1AP message is one of the following: an RRC message type, an F1AP message type, or an RRC message type and an F1AP message type.

Various aspects of the present disclosure generally relate to wireless communication. In some aspects, a user equipment (UE) may receive a measurement resource. The UE may perform a Layer 3 (L3) measurement of the measurement resource using a first polarization that is dedicated for performing L3 measurements and that is supported by the UE. Numerous other aspects are described.

A system for discovering tunnel neighbors is provided. During operation, the system can establish, at a first switch, a tunnel with a second switch in an overlay tunnel fabric that includes the first and second switches. Upon establishing the tunnel, the system can generate a discovery packet comprising a first set of discovery information indicating the configuration and capabilities of the first switch associated with the tunnel. The system can send the discovery packet to the second switch via the tunnel prior to initiating payload data communication via the tunnel. The system can also receive a second discovery packet from the second switch via the tunnel. The second discovery packet can include a second set of discovery information indicating the configuration and capabilities of the second switch associated with the tunnel. The system can then store the second set of discovery information in an entry of a data structure.

A spectrum management database and server provides measurement and modeling of RF (Radio Frequency) cloud interference in near real-time results for efficient utilization of the precious spectrum. This shared spectrum defines a scarce resource shared among all wireless devices of the universe in frequency, time, and space. Near real-time forecasting of the RF cloud interference is beneficial in pursuit of a path to the optimal utilization of spectrum and a liberated spectrum management. A spectrum management server gathers interference information including bandwidth ranges and locations from a plurality of deployed devices, receives requests for bandwidth, and satisfies the request by allocating a non-interfering bandwidth at a requesting location based on the stored indications

The present disclosure describes a computer-implemented method that includes: in response to receiving information that a base station from the network of base stations at the geo-exploration site has relocated, obtaining a geographic positioning information of the relocated base station; accessing a database encoding geographic positioning information of base stations from the network of base stations at the geo-exploration site, along with respective frequency assignment information for each base station; analyzing an interference pattern between the base station that has relocated and other base stations from the network that are within a threshold distance of the relocated base station, wherein the relocated base station is being considered for a radio frequency assignment based on the geographic positioning information; and determining the radio frequency assignment for the relocated base station based on the interference pattern.

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.

Provided is a method, performed by an electronic device, of scheduling downlink (DL)/uplink (UL) traffic for an augmented reality (AR) service based on a wireless local area network (WLAN). The method includes a period arrangement operation of arranging a contention period (CP) at both sides of a contention free period (CFP) in a preset capture interval (I) and an AR traffic allocation operation of allocating AR traffic including UL traffic and DL traffic to the CFP.

The present technology is generally directed to dynamically adding network resources based on an application function (AF) notification. The present technology can determine, by an AF of a service provider, a network congestion on a network, the network congestion indicating that network resources for servicing a user device using services of the service provider do not meet corresponding Quality of Service (QoS) requirements. Further, the present technology can transmit a notification by the AF to a core network of a network provider to request additional network resources to be allocated for servicing the user device, the network provider providing network connectivity for the user device to receive the services provided by the service provider.